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1
REMOVAL OF LINDANE FROM WATER
USING ADVANCED OXIDATION TECHNIQUES
BY
SANAULLAH KHAN
NATIONAL CENTRE OF EXCELLENCE IN
PHYSICAL CHEMISTRY,
UNIVERSITY OF PESHAWAR−PAKISTAN
JULY, 2014
2
REMOVAL OF LINDANE FROM WATER
USING ADVANCED OXIDATION TECHNIQUES
A dissertation submitted to the University of Peshawar in partial fulfillment
of the requirement for the degree of
DOCTOR OF PHILOSOPHY
IN
PHYSICAL CHEMISTRY
BY
SANAULLAH KHAN
NATIONAL CENTRE OF EXCELLENCE IN
PHYSICAL CHEMISTRY, UNIVERSITY OF
PESHAWAR, PESHAWAR, PAKISTAN
JULY, 2014
3
4
NATIONAL CENTRE OF EXCELLENCE IN
PHYSICAL CHEMISTRY, UNIVERSITY OF
PESHAWAR, PESHAWAR, PAKISTAN
JULY, 2014
It is recommended that the dissertation prepared by
SANAULLAH KHAN
entitled “Removal of Lindane from Water using Advanced
Oxidation Techniques”
be accepted as a fulfillment of the requirement for the degree
of
DOCTOR OF PHILOSOPHY
IN
PHYSICAL CHEMISTRY
APPROVED BY
(PROF. DR. HASAN M. KHAN) (PROF. DR. M. SALEEM KHAN)
Research Supervisor Director
_________________________________ ________________________________
External Examiner Internal Examiner
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DEDICATION
My thesis is dedicated to the most beloved personality of Allah (Subhana-hu Wa
Ta’ala), Prophet Mohammed (PBUH). I dedicate my effort of writing my dissertation to
my respectable father whose continue love and kindness, and encouragement always
helped me to keep my determination steadfast.
Sanaullah Khan
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TABLE OF CONTENTS
Title Page No
Title i
Table of Contents vi
Acknowledgements x
Abstract xii
Keywords xiv
List of abbreviations xv
List of publications xviii
1. INTRODUCTION 1
1.1 Water Pollution Issue 1
1.2 Persistent Organic Pollutants (POPs) 4
1.3 Lindane Contamination 6
1.3.1 Uses of lindane 8
1.3.2 Toxicity of lindane 9
1.4 Literature Review 11
1.4.1 Lindane degradation by various methods 11
1.4.1.1 Physical methods 11
1.4.1.2 Biological methods 13
1.4.1.3 Advanced oxidation processes (AOPs) 14
1.4.1.3.1 Fenton and photo-Fenton reactions 15
1.4.1.3.2 UV/H2O2 process 16
1.4.1.3.3 Ozonation 17
1.4.1.3.4 Reduction by zero-valent iron 19
1.4.1.3.5 Electrolysis 19
1.4.1.3.6 Microwave irradiations 20
1.4.1.3.7 Ionizing radiations 20
1.4.1.3.8 TiO2 photocatalysis 22
1.4.1.3.9 Sulfur radical-based AOPs 24
1.5 Aims and objectives of the Present Work 25
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2. EXPERIMENTAL 27
2.1 Materials 27
2.2 Sample Collection 28
2.3 Preparation of Solutions 30
2.4 Extraction Technique 30
2.5 Reactor Design 31
2.5.1 Gamma rays reactor 31
2.5.2 UV reactor 32
2.5.3 UV/Vis reactor 32
2.5.4 Solar reactor 34
2.5.5 Fluorescence light reactor 34
2.5.6 Dark reactor 35
2.6 Calibration of Radiation Sources 35
2.6.1 Calibration of gamma radiation source 35
2.6.2 Calibration of UV radiation source 38
2.7 Qualitative/Quantitative Analysis of Lindane and other Products 40
2.7.1 Gas chromatography-electron capture detector (GC/ECD) 40
2.7.2 Gas chromatography-mass spectrometry (GC/MS) 40
2.7.3 Ion chromatography (IC) 41
2.7.4 High performance liquid chromatography (HPLC) 42
2.7.5 Total organic carbon (TOC) analyzer 42
2.7.6 UV spectrophotometer 42
2.8 Synthesis of Sulfur Doped TiO2 Photocatalyst 43
3. RESULTS AND DISCUSION 49
3.1 Determination of Lindane in Field Water Samples of District
Swabi, KP, Pakistan 49
3.1.1 Optimization of the GC/ECD method for lindane analysis 49
3.1.2 Precision, accuracy, reproducibility and relative recoveries of
the method 49
3.2 Application of the optimized GC/ECD method to Real Water Samples 54
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3.3 Gamma Radiation-induced Degradation of Lindane in Water 57
3.3.1 Kinetic Studies of the Gamma Radiation-induced Degradation of
Lindane 58
3.3.1.1 Effect of initial solute concentration 59
3.3.1.2 Effect of solution pH 62
3.3.2 Scavenging effects on gamma radiation-induced degradation
of aqueous lindane 65
3.3.2.1 Radiolysis of lindane in N2-saturated solution (control experiments) 66
3.3.2.2 Radiolysis of lindane in aerated solution (natural condition) 66
3.3.2.3 Radiolysis of lindane in N2-saturated 60 mM i-PrOH solution
(reductive conditions) 66
3.3.2.4 Radiolysis of lindane in N2O-saturated solution (oxidative conditions) 67
3.3.3 Role of individual reactive species in lindane degradation 69
3.3.4 Dechlorination studies of lindane 75
3.3.5 Effect of common inorganic ions on lindane degradation 76
3.3.6 Effect of H2O2 on lindane degradation 79
3.3.7 Effect of natural organic matter (NOM) and synthetic organic
pollutants 79
3.3.8 Pulse radiolysis of lindane–Hydrated electron rate constants
(eaq− + lindane) 82
3.3.9 Competition kinetics–Hydroxyl radical rate constant
(•OH + Lindane) 83
3.3.10 Variation of solution pH during irradiation 84
3.3.11 Identification of by-products and possible reaction pathways 86
3.3.12 Removal efficiency of lindane 89
3.4 Degradation of Lindane by Photochemical Oxidation 100
3.4.1 Degradation of lindane by solely PMS or ferrous iron (Fe2+)
and direct UV photolysis 100
3.4.2 PMS activated by ferrous ion: Fe2+/PMS system 103
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3.4.3 Fe2+/PMS system assisted by tube-light radiation: Tube-light/Fe2+/PMS
system 105
3.4.4 PMS activated by UV radiation: UV/PMS system 108
3.4.5 UV/Fe2+/PMS system 113
3.4.6 Kinetics of UV/PMS oxidation 117
3.4.6.1 Effect of initial concentrations of lindane 118
3.4.6.2 Effect of solution pH 122
3.4.6.3 Effect of humic acid on the UV/PMS process 123
3.4.6.4 Effect of inorganic anions on the UV/PMS process 126
3.4.7 Mineralization study 129
3.4.8 Oxidant residue analysis of UV/Fe2+/PMS process 135
3.4.9 Product analysis and reaction mechanism of the UV/PMS system 138
3.4.10 Degradation of trichlorobenzene (TCB) by photochemical oxidation 144
3.5 Hydroxyl radical based AOP using UV activated H2O2 for lindane
degradation 150
3.5.1 Comparison of the UV/PMS system with UV/H2O2 system 152
3.6 Photocatalytic activity of sulfur doped TiO2 (S-TiO2) and TiO2 under
Visible light 157
3.6.1 Factors affecting efficiency of photocatalytic activity of S-TiO2
Process 161
3.6.1.1 Effect of solution pH 161
3.6.1.2 Effect of initial concentration of lindane 162
3.6.1.3 Effects of inorganic oxides. i.e., PS and PMS on the degradation
of lindane in the simulated solar/S-TiO2 system 168
4. CONCLUSIONS AND FUTURE PERSPECTIVES 172
4.1 Conclusions 172
4.2 Future Perspectives 174
REFERENCES 176
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ACKNOWLEDGEMENTS
My first and foremost gratitude goes to ALLAH (Subhanahu Wa Ta’ala)”, who
enabled me to finish this great job, which otherwise was very difficult for me to do
without His Wills. My beloved prophet “Mohammad (Peace be upon him)”, whose deep
love always inspired me, deserves highest gratitude after ALLAH (SWT).
Next, I would like to present my great appreciations to my kind supervisor Prof. Dr.
Hasan M. Khan, former Director of the Centre, for his motivation, encouragement, co-
operation, and friendly behavior. His critical discussion on many research issues always
inspired me and led me to submit my thesis in the present form.
I am very thankful to Prof. Dr. M. Saleem Khan, Director, National Center of
Excellence in Physical Chemistry, University of Peshawar, for his sympathetic attitude
and provision of all sorts of facilities during the course of my Ph.D research work.
I am really grateful to Prof. Dr. Dionysios D. Dionysiou, University of Cincinnati,
Cincinnati, USA, for his help, guidance, and for providing all kinds of research facilities
during six month research work at the University of Cincinnati.
I am truly thankful to Xuexiang He and Changseok Han, Ph.D research students in
the University of Cincinnati, for their sincere help in the research work during my stay at
the University of Cincinnati.
I am grateful to my colleagues, Drs. Javed Ali Khan, Murtaza Sayed and Noor
Samad Shah for their help and cooperation in many ways, especially in experimental
work as well as in results and discussions. My sincere appreciations also go to my other
lab fellows, Mr. Shah Nawaz, Dr. M. Ismail, Faiza Rehman, Fazl-e-Hadi, Fayaz Ali,
Razaullah, and Jehangir Khan for their friendship and necessary help. I really enjoyed
their company during the course of my Ph.D study.
My good wishes go to all staff members of the National Center of Excellence in
Physical Chemistry, University of Peshawar for their respective help and support.
I am also thankful to the staff members of the Nuclear Institute for Food and
Agriculture (NIFA), Peshawar, specially the Director, Dr. Ihsanullah and Mr. Tariq
Nawaz for providing research facilities at NIFA, particularly the gamma irradiator.
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Finally, my cordial thanks and appreciations go to my parents, brothers especially
Hamidullah Khan and Shafiullah Khan, uncle, Prof. Ghani-ur-Rehman, sisters, wife
and my friends particularly Zia-ur-Rehman, Tariq Mahmood and Shams-ul-Haq, for
their infinite love, sympathy, motivation, encouragement and prayers.
The Higher Education Commission of Pakistan (HEC) is highly acknowledged for
providing financial assistance through 5000 Indigenous Ph.D fellowships throughout the
Ph.D degree program. HEC is also acknowledged for granting fellowship under the
International Research Support Initiative Program (IRSIP), to carry out a part of my Ph.D
research work at the University of Cincinnati, OH, USA.
Sanaullah Khan
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ABSTRACT
Organochlorine pesticides are highly persistent and the most emerging endocrine
disrupting chemicals in the environment. In this study, several emerging advanced
oxidation processes (AOPs), i.e., gamma ionizing radiation, sulfate radical based-AOPs,
and non-metal doped TiO2 photocatalysis were investigated for the degradation of
lindane in aqueous solution. The effects of water quality and process parameters, such as
solution pH, initial concentration of pollutant, initial concentration of oxidant and/or
catalyst, oxidant/catalyst molar ratios, presence of inorganic ions and natural organic
matters, were studied. All of the studied AOPs showed high efficiency, and ultimately led
to complete degradation of lindane under different conditions. The degradation of lindane
by the studied AOPs followed pseudo-first order kinetics. The observed pseudo-first
order rate constant decreased while degradation rate increased with the increasing initial
concentration of lindane. Different initial pH presented a different effect on lindane
degradation. The highest efficiency of lindane degradation was achieved at neutral pH.
The presence of co-existing background constituents, such as natural organic matter
and/or inorganic anions (CO32−, HCO3
−, SO42−, Cl−, NO3
−, and NO2−) presented a
different effect on lindane degradation, based on the competition of these constituents
with lindane for the reactive radicals generated in various AOPs. The results were
discussed in terms of reactivity of hydroxyl radical (•OH), sulfate radical (SO4•−) and
hydrated electron (eaq−) with lindane. Hydrated electron was found to be the most reactive
species, as suggested from its high second-order rate constant of 1.26 × 1010 M˗1 s−1 (as
compared to 1.3 × 109 and 6.8 × 108 M−1 s−1 for SO4•− and •OH, respectively), determined
via competition kinetics method. Based on the detected by-products through GC-MS
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analysis, a plausible reaction mechanism was proposed for UV activated
peroxymonosulfate process (i.e., UV/HSO5−), suggesting dechlorination, chlorination,
dehydrogenation and hydroxylation via •OH and/or SO4•− attack. The studied AOPs also
showed significant efficiency in dechlorination and mineralization of lindane. The
addition of 0.2 mM peroxymonosulfate (HSO5−) showed a large enhancing effect on
visible and solar light-assisted sulfur-doped titanium dioxide (S-TiO2) photocatalysis of
lindane. The reaction mechanism revealed that •OH and SO4•− reacted with lindane via
hydrogen abstraction pathway, while eaq− followed dissociative electron capture
mechanism. Trichlorobenzene (TCB), a typical reaction by-product of lindane, was
readily degraded by various UV/oxidant processes tested. Assessment of lindane residues
in the surface water samples, in different regions of district Swabi, Khyber
Pakhtoonkhwa (Pakistan), was carried out; indicating thirteen out of the eighteen samples
analyzed, were contaminated by varying amounts of lindane. The outcome of this study
will provide useful scientific information on the effectiveness of gamma radiations, S-
TiO2 photocatalysis, and various sulfate radical based-AOPs on the degradation of
organic compounds, especially problematic organochlorine pesticides.
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Keywords: Lindane; Gamma radiations, Advance Oxidation Processes (AOPs);
UV/Peroxymonosulfate; S-TiO2 photocatalysis; Rate constants; Water treatment.
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LIST OF ABBREVIATIONS
AOPs Advance oxidation processes
AOTs Advanced oxidation technologies
ATSDR Agency for toxic substances and disease registry
a.u arbitrary unit
BET Brunauer-Emmett-Teller
BOD Biological oxygen demon
CNS Central nervous system
COD Chemical oxygen demon
CP Chlorophenol
CSTR Continuous stirred tank reactor
DBCP 1, 2-dibromo-3-chloropropane
DBPs Disinfection by-products
EDCs Endochrine disrupting chemicals
EI Electron impact
FBR Fix bed reactor
FA Fulvic acid
FSD Food and Soil Division
GAC Granular activated carbon
GC/ECD Gas chromatograph electron capture detector
GC/MS Gas chromatograph mass spectrometry
HA Humic acid
HCB Hexachlorobenzene
HCH Hexachlorocyclohexane
HPLC High performance liquid chromatograph
IC Ion chromatography
IERC International agency for research on cancer
KP Khyber Pakhtoonkhwa
LOD Limit of detection
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LOQ Limit of quantification
MAL Maximum acceptable level
MC Mechanochemical
MOAFF Ministry of Agriculture, Forestry, and Fisheries
MTBE Methyl tert-butyl ether
MW Microwave
ND Not detected
NIFA Nuclear institute for food and agriculture
NIST National institute of standards and technology
NOMs Natural organic matters
OCPs Organochlorine pesticides
PAC Powdered activated carbon
PCBs Polychlorinated biphenyls
PCE Tetrachloroethene
PCPs Pharmaceuticals and personal care products
PF Photo-Fenton
PMDS Polydimethylsiloxane
PMS Peroxymonosulfate
POPs Persistent organic pollutants
PS Persulfate
RO Reverse osmosis
ROSs Reactive oxygen species
RSD Relative standard deviation
SPME Solid phase micro extraction
SLA Solar light activity
SR/AOPs Sulfate radical-based advanced oxidation processes
S/N signal-to-noise ratio
TCE tetrachloroethylene
TOC Total organic carbon
TTIP Titanium (IV) isopropoxide
17
UNEP United nation environmental programme
UNO United nation organization
US EPA United state environmental protection agency
UV Ultra Violet
VLA Visible light activity
WHO World Health Organization
ZVI Zero-valent iron
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LIST OF PUBLICATIONS
1. S. Khan, X. He, H.M. Khan, D. Boccelli, D.D. Dionysiou, Efficient degradation
of lindane in aqueous solution by iron (II) and/or UV activated
peroxymonosulfate, Journal of Photochemistry and Photobiology A: Chemistry,
316 (2016) 37-43.
2. H.M. Khan, A.A. Khan, S. Khan, Application of DNA comet assay for detection
of radiation treatment of grams and pulses, 48 718-723.
3. M. Sayed, M. Ismail, S. Khan, S. Tabassum, H.M. Khan, Degradation of
ciprofloxacin in water by advanced oxidation process: kinetics study, influencing
parameters and degradation pathways, Environmental technology, (2015) 1-13.
4. M. Sayed, M. Ismail, S. Khan, H.M. Khan, A comparative study for the
quantitative determination of paracetamol in tablets using UV-Visible
spectrophotometry and high performance liquid chromatography, Physical
Chemistry 17(1) (2015) 1-5.
5. S. Khan, C. Han, H.M. Khan, D.L. Boccelli, D.D. Dionysiou, Sulfur-doped TiO2
for photocatalytic degradation of lindane under visible and solar light irradiation:
Strong enhancement due to peroxymonosulfate addition (submitted to Chemical
engineering journal).
6. S. Khan, X. He, J.A. Khan, H.M. Khan, D.L. Boccelli, D.D. Dionysiou, Kinetics
and mechanism of sulfate radical- and hydroxyl radical-induced degradation of
highly chlorinated pesticide lindane in UV/peroxymonosulfate system (submitted
to Chemical engineering journal).
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1. INTRODUCTION
1.1 Water Pollution Issue
Water is a critical resource and basic necessity for each and every individual on land.
The shortage of freshwater resources worldwide will only become more critical as the
world population increases and the climate changes. The rapid progress in the field of
agriculture and industrialization though contributed a lot to the economic development of
nations; it has resulted in heavy losses to society in terms of water, soil and air pollution
(Reddy and Behera, 2006). Groundwater and surface waters that constitute an integral
part of the continental water cycle can transport and spread contaminants from spatially
limited industrial areas or mining areas to extensive downstream regions. This is in
addition to spreading of more diffuse contamination, such as from pesticides distributed
over agricultural fields and vehicular transport system. Water resources are affected by
man-made pollution worldwide to such an extent that restoration to pristine conditions is
not achievable (Tornqvist et al., 2011).
The significance of accessibility of good quality drinking water can be recognized
by the press release of UNO Secretary General on world water day 2002: “An estimated
1.1 billion people lack access to safe drinking water, 2.5 billion people has no access to
proper sanitation, and more than 5 million people die each year from water-related
diseases–10 times the number killed in wars, on average, each year. All too often, water
is treated as an infinite free good. Yet even where supplies are sufficient or plentiful, they
are increasingly at risk from pollution and rising demand. By 2025, two thirds of the
world's population is likely to live in countries with moderate or severe water shortages”
(UNO, 2002). Water is the most essential element for existence of all kinds of life on the
20
Earth. Most part of the world’s water resources is confined to occasions as saline water;
only 3% is available as freshwater. Out of the total amount of freshwater, only 0.01% is
available for human use (Hinrichsen and Tacio, 1997). Unfortunately, this small
proportion of freshwater is constantly polluted due to rapid population growth,
urbanization and industrialization and gross agriculture activities. According to UNO
report, population of the world is regularly increasing, while the existing fresh water
resources are declining day by day. As a result, many nations of the world, particularly
some countries in Middle East, Africa, and South Asia will have severe problems of
water shortage in the next two decades (UNO, 2002).
Although water contamination is a global issue, developing countries are facing
extra problems because of deprived management and poor monitoring policy. Like other
developing nations, there is severe public health concern in Pakistan due to low quality
water. Pakistan ranks at number 80 among 122 nations regarding drinking water quality.
Drinking water sources, both surface and groundwater are contaminated with bacteria,
toxic metals and pesticides throughout the country. Various drinking water quality
parameters set by the World Health Organization (WHO) are frequently violated.
Different anthropogenic sources, like improper disposal of municipal and industrial
effluents and indiscriminate usage of pesticides for agriculture purposes are primarily
involved in the deterioration of water quality. Microbial and chemical pollutants are the
main factors responsible exclusively or in combination for various public health problems
(Azizullah et al., 2011). The country has essentially exhausted its available water
resources; it is considered as water stressed and is likely to have a water scarcity in the
near future (Hashmi et al). The water precipitation rate is lower than the evaporation rate
21
in the country. This causes a continuous decrease in water quantity in its rivers, lakes and
diminishing the groundwater as well. The problem is further provoked by factors like
long droughts and lack of construction of new water reservoirs (Ullah et al., 2009). This
decrease in water quantity coupled with increasing demand resulted in severe water
shortage in almost all sectors of the country. Large number of organic recalcitrants,
including solvents, pesticides, paints, dyes, phenols, petrochemicals, polymers,
pharmaceuticals and personal care products (PCPs) are continuously added into the water
resources since the early development in the field of industrialization. All these chemicals
are highly toxic to animals, and many of these substances can be readily absorbed
through the skin. These factors can badly affect higher classes of mammals including
human beings (Sheoran, 2008a).
Chemical pollution of surface waters presents a hazard to the aquatic environment
as well as a threat to human health. Among various chemicals, pesticide contamination of
surface water resources is a major water quality issue throughout the world.
Pesticide is a general term for substances, which are used to poison pests (weeds,
insects, molds, rodents etc.). The pesticides most acutely dangerous to humans are
insecticides and rodenticides. Synthetic pesticides have been popular with farmers,
because of their efficacy and cost effectiveness, but they also have huge environmental
costs (Agrawal, 2010). Due to new arrivals in farming practices and intensive revolution
in the field of agriculture, the worldwide production and consumption of pesticide has
significantly increased in recent years. The extensive use of pesticides for agricultural
and several other purposes has resulted in the occurrence of pesticides residues in various
environmental segments of the world. Pesticide residues reach the aquatic environment
22
through direct run-off, leaching, careless disposal of empty containers, equipment
washing, etc. Pesticide contamination of surface waters has been well documented
worldwide and constitutes a major issue that gives rise to concerns at local, regional,
national and global scales (Planas et al., 1997; Huber et al., 2000). So, it is clear that the
strategy to find solutions to this immense problem by developing cheap and green
remediation technologies is very important.
1.2 Persistent Organic Pollutants (POPs)
Persistent organic pollutants (POPs) are carbon-based synthetic organic products
and by-products of priority concern for community of environmental scientists and
engineers, worldwide (Tanabe et al., 1994; Hansen 1998). POPs constitute a diverse
group of organic substances with some intrinsic physical-chemical properties, such as
toxicity, persistency, bioaccumulative and long-range transportable nature, which dictate
their environmental behavior (Wania, 2003, 2005). There are many thousands of
persistent chemicals, often coming from certain series or `families' of chemicals (e.g.
there are theoretically 209 different polychlorinated biphenyls, differing from each other
by level of chlorination and substitution position). There is no fixed opinion about the
half-life of a substance in a particular media to be conferred `persistent'; however,
generally a POP has a half-life of several days in the atmosphere and several years in the
soil and sediment (Jones and de Voogt, 1999). POPs are typically `water-hating' and `fat-
loving' chemicals. So, they prefer lipids rather than the aqueous environment of cells
inside living organisms and get stored in fatty tissue. POPs have the tendency to enter the
gas phase under environmental temperatures. Hence, they may volatilize from water
23
bodies, soils and vegetation into the atmosphere. Low POP levels might be increased by
biomagnifications through the transmission process in the food chain (Tieyu et al., 2005).
Environmental occurrence of POPs is a global rather than a regional problem,
because the POPs used in tropical regions will be carried by long-range atmospheric
transport to polar and environmentally pristine areas, such as the Arctic region (Hargrave
et al., 1988; Patton et al., 1989; Barrie et al., 1992). As a result, POPs pollution has
touched every region in the world. POPs have been reported to cause variety of effects
including immunologic, teratogenic, carcinogenic, reproductive, developmental,
behavioral, neurological and endocrine problems in organisms (Pages et al., 2002).
Because of massive adverse effect on environment, a great deal of attention is paid to
POPs contamination problems, and strong action has been taken by many developed and
developing nations (Tieyu et al., 2005). In 2004, the Stockholm Convention on POPs
(POPs Treaty) that was adopted by the United Nations Environmental Programme
(UNEP) came into force and aims to protect human health and the environment from
negative effects of POPs by reducing or eliminating releases of POPs to the environment.
At first, the treaty promotes the global regulations on the production and usage of twelve
substances, the so-called “dirty dozen” which consists of eight kinds of pesticides,
including dieldrin, aldrin, endrin, chlordane, heptachlor, DDT, toxaphene, mirex, two
kinds of industrial chemicals (polychlorinated biphenyls (PCBs) and hexachlorobenzene
(HCB)), and two kinds of by-products (polychlorinated dibenzofurans and
polychlorinated dibenzo-p-dioxins) (Hosomi, 2001, 2002, UNEP, 2001). In 2009,
hexachlorocyclohexane (HCH) among eight other compounds, was added as new
24
Stockholm Convention POPs, thus extending the original POPs list (12) to a total of 21
members (Vijgen et al., 2011).
Organochlorine pesticides (OCPs) are one of the most important persistent organic
pollutants (POPs) and have been of great concern around the world owing to their chronic
toxicity, persistence and bioaccumulation (Willett et al., 1998). OCPs are ubiquitous
anthropogenic environmental contaminants posing great threats to ecosystems and human
health (Kalajzic et al., 1998). Although the application of these chemicals has been
banned or restricted in many countries, especially the developed ones, some developing
countries are still using these compounds because of their low cost and versatility in
industry, agriculture and public health (Tanabe et al., 1994, Nasir et al., 1998). Among
the OCPs, lindane has been shown to be very persistent, bioaccumulative and toxic to
humans (Moore and Walker., 1964, Sarkar et al., 2008).
1.3 Lindane Contamination
Lindane is an organochlorine insecticide which has been extensively used on wide
varieties of fruit, grain and vegetable crops and conifer trees for control of leaf-eating
insects and pests (Ware and Whitacre, 2004). Lindane is also known as gamma-
hexachlorocyclohexane (γ-HCH) since it is made up of at least 99% of the gamma isomer
of hexachlorocyclohexane (HCH). The chemical structure of lindane is shown in Figure
1.1. HCH is available in two formulations: technical HCH and technical lindane. A total
of eight HCH isomers denoted by Greek letters α, β, γ, δ, ε, ζ, η and θ have been
identified in technical HCH. However, only the α, β, γ, δ, and ε-isomers, varying in the
following percentages: α: 60-70%, β: 5-12%, γ: 8-15%, δ: 6-10%, and ε: 3-4%, are stable
isomers of technical HCH, while lindane is almost pure γ-isomer (Rankenberger., 2002).
25
Hexachlorocyclohexane was initially synthesised in 1825, but the pesticidal properties of
HCH were recognized in 1942 (Metcalf., 1955). Commercial production of technical-
grade HCH began in 1943 by Imperial Chemical Industries Ltd; UK (ICI) and use started
up in the United Kingdom (Li et al., 2011). HCH can be synthesised by photochlorination
of benzene. When the resulted product is treated with acetic acid or methyl alcohol,
99.9% pure γ-HCH isomer (i.e., lindane) is obtained upon fractional crystallization
process. The γ-isomer (CAS Registry No. 58-89-9) is the isomer with the highest
pesticidal activity; however, technical mixtures of all isomers (CAS Registry No. 608-73-
1) have been widely used as commercial pesticides (Metcalf., 1955). Total global
production and use of the different HCH isomers is difficult to determine, and estimates
vary considerably. Voldner and Li estimated total use of technical-grade HCH and
lindane to be 550 000 and 720 000 metric tons, respectively (Voldner and Li., 1995).
However, later calculations by Li and co-workers placed total cumulative world
consumption of technical-grade HCH as high as 6 million metric tons (Li et al., 1998).
More recently, total global usage of technical HCH between 1948 and 1997 was
estimated to be around 10 million metric tons (Li., 1999). Environmental and human
health concerns led to the banning of technical-grade HCH in many countries during the
1970s. China, India, and the former Soviet Union remained the largest producers and
users of HCH in the early 1980s. In 1980, the annual consumption of technical HCH in
two Asian countries, India and China, accounted for more than 84% of the total technical
HCH consumption in the world. Of the 90 000 tons applied in 1990, 51 000 tons was
used in India. In China, the production of HCH was banned in 1983, but residual stocks
may have been used until 1985 (Li et al., 1998). In1990, although increased in India, the
26
usage of technical HCH decreased dramatically among other countries. In 1990,
production of technical-grade HCH was also prohibited in the former Soviet Union, and
use of residual stocks was restricted to public health and specific crop uses. Literature
survey shows that the leading lindane consuming countries include both developing
countries as well as developed countries. In 1990, France, Italy, Niger, Canada, the
United States, India and China were among the leading lindane consuming countries with
annual usage more than 100 tons (Li et al., 1996).
1.3.1 Uses of lindane
Lindane has been released to the environment during its formulation process and
through its use. Lindane is used as an insecticide on fruit, grain and vegetable crops, in
warehouses and in public health measures to control insect-borne diseases (Li et al.,
1998). Together with fungicides, lindane can also be used as a seed treatment agent for
barley, corn, oats, rye, sorghum, and wheat. Lindane is also used in a variety of domestic
and agricultural applications, such as dips, sprays and dust for livestock and domestic
pets (Li., 1999). The forestry industry also uses lindane to control pests on cut logs
(Donald et al., 1997). Lindane is also used topically for the treatment of head and body
lice and scabies; it is available in 1 percent preparations as a lotion, cream, or shampoo
(Nordt and Chew., 2000). The various formulations of lindane and technical HCH have
many trade names, including Agrocide, Ben-Hex, Gammexane, Kwell, Quellada,
Lindatox, and Tri-6 (Sang et al., 1999). Extremely low cost of lindane led to its wide use,
particularly in some developing countries (Abhilash and Singh, 2009). Lindane residues
persist in the environment, undergo volatilization in tropical conditions, migrate to long
distances with air current, deposit in colder regions, and cause widespread contamination;
27
the γ-HCH-residues reach human body via food chain and get biomagnified at each
trophy level (Benimeli, 2008). Lindane contamination has been detected in air, surface
water, groundwater, sediment, soil, fish and other aquatic organisms, wildlife, food, and
humans (Iwata et al., 1994, Li, 1999). Human exposure results primarily from medicinal
use and from ingestion of contaminated plants, animals, and animal products. Lindane
has not been found to be a major contaminant of drinking water supplies in U.S.A
(ATSDR, 2005)
The commercial application of lindane was launched in the decade following
World War II and was used extensively in Europe, U.S.A., and other developed countries
in 1970s. Lindane is considered to be highly toxic to aquatic organisms, and moderately
toxic to birds and mammals. People who are occupationally exposed to it are advised to
avoid its contact with eyes, skin and via inhalation. Symptoms of acute toxicity in
humans include mild skin irritation, headache, dizziness, seizures, diarrhea, nausea,
vomiting and even convulsions as well as effects on the gastrointestinal tract,
cardiovascular and musculoskeletal systems (Sang et al., 1999).
1.3.2 Toxicity of lindane
Lindane is a well known reproductive and developmental toxicant with a pattern
of effects suggesting an endocrine-related mechanism (Pages et al., 2002, Traina et al.,
2003). Lindane can inhibit the synthesis of DNA, RNA, protein and carbohydrate
contents in animals (Al-Chalabi and Al-Khayat, 1989). It has adverse effects on the
central nervous system (CNS) and has teratogenic, immunotoxic, and neurotoxic
properties (Hayes, 1982). Acute and chronic exposure of lindane has been shown to
produce marked neurological and hepatotoxic effects in experimental animals (Oesch,
28
1982). It produces neurotoxic, hepatotoxic and uterotoxic effects in rats (Criswell and
Loch-Caruso, 1999). The neurotoxicity of lindane involving different manifestations of
hyperexcitability and, at high doses, convulsions have been extensively reported (Wooley
et al., 1985, Tusell et al., 1988).
With this comment, lindane is considered as a possible human carcinogen by the
United States Environmental Protection Agency (US EPA) and the International Agency
for Research on Cancer (PHG, 1999). WHO has classified lindane as a “moderately
hazardous” substance (WHO, 2004).
Figure 1.1. Chemical structure of lindane
29
1.4 Literature Review
Lindane and other HCHs have long been a well studied class of organochlorine
compounds with respect to environmental fate and effects. Lindane has been used
extensively in both agricultural and pharmaceutical commercial applications for more
than fifty years (Walker et al., 1999, Sarkar et al., 2008). Residues of lindane have been
widely detected in environmental water, sediment, and organism samples. Because of
potential water contamination, there is a need to develop new technological approaches
for rapidly destroying lindane and other POPs in aqueous solution.
1.4.1 Lindane degradation by various methods
Despite its persistence, lindane degradation has been reported using various
conventional methods as well as advanced oxidation technologies (AOTs). The
conventional decontamination techniques consist of physical methods (adsorption on
activated carbon, coagulation-flocculation, mechanochemical treatment, membrane
technology and reverse osmosis) and biological methods i.e. biotransformation.
1.4.1.1 Physical methods
Adsorption process involves the separation of a substance from one phase
accompanied by its accumulation at the surface of other. Activated carbon is a highly
porous, amorphous solid with large micropore volume and high surface area and
adsorption onto activated carbon is considered an advanced water treatment process for
the removal of aqueous-dissolved organic pesticides. Both activated carbon types, i.e.
granular activated carbon (GAC) and powdered activated carbon (PAC) can be used for
the adsorption of pesticides. However, GAC is mainly used due to the advantages of
relatively lower carbon application rates, easier handling and the possibility for
30
regeneration of adsorbent (El-Dib, et al., 1975, Pirbazari, et al., 1991). Thacker and co-
workers studied the adsorption of aqueous lindane on granular activated carbon (GAC),
using two different types of reactors i.e. a continuous stirred tank reactor (CSTR) and fix
bed reactor (FBR) systems. The carbon dose required to treat raw water having initial
concentrations of 5-10 μg/L of lindane to <2 μg/L was 0.8 and 0.9 g/L for (CSTR) system
and 0.5 and 0.6 g/L for (FBR) systems, respectively. This study provides useful results
for reducing the concentration of lindane down to the potable level (<2 μg/L), but it does
not give information about the dynamics of the system (Thacker et al., 1997). Kouras and
co-workers studied the adsorption of lindane from aqueous solutions onto powdered
activated carbon (PAC) in batch experiments. The results indicated that PAC doses
greater than 20 mg/L were found to be necessary in order to reduce lindane from initial
concentration of 10 mg/L down to 0.1 mg/L within 1 h contact time. pH of the solution
did not show any effects on the adsorption efficiency (Kouras et al., 1998).
Membrane technology comprising of microfiltration or ultra filtration process has
been remarked among innovative technologies, because no chemical agents used and
high quality water is constantly produced with simple automation of process (Sadr
Ghayeni et al., 1996, Comerton et al 2005, Wintgens et al., 2005).
Reverse osmosis has been gradually finding application in the treatment of a
variety of domestic, industrial, and hospital wastewaters (Plakas and Karabelas, 2012).
Chian and co-workers studied the removal of pesticide with reverse osmosis using
different kinds of membranes. The efficiency of the process was found to vary with the
kind of the membrane used. It was seen that non-cellulosic membranes showed better
efficiency for removal of pesticides than cellulosic type membrane (Chian et al., 1975).
31
Mechanochemical (MC) treatment is another developed technology of pollutant
removal approved by the Ministry of Agriculture, Forestry, and Fisheries of Japan
(MOAFF). This technology has successfully been used for degradation various kinds of
hazardous chemicals, particularly organochlorine pesticides in recent decades (Hall et al.,
1996, Loiselle et al., 1996, Tanaka et al., 2003, Birke et al., 2004). Nomura and co-
workers studied the applicability of the mechanochemical (MC) treatment technology for
the destruction of lindane in batch experiments (Nomura et al., 2012). The degradation of
lindane ultimately led to the formation of trichlorobenzenes (TCB) as final by-product.
Further degradation products (dichlorobenzenes, monochlorobenzene, and benzene) were
also detected but in limited amount. Traces of methane and ethane were also detected,
suggesting cleavage of the C–C bonds of the cyclohexane ring and hydrogenation.
1.4.1.2 Biological methods
Bioremediation, which incorporate the useful utilization of microorganism for the
degradation of target pollutants, is a competent technique for the biological treatment of
industrial wastes and contaminated soils (Alexander, 1994, Crawford and Crawford,
2005). Lindane and other HCHs are known to be susceptible to attack by anaerobic
microorganisms that exist in sewage sludge, river or lake sediments, or even in the soil of
flooded agricultural fields (Hill and McCarty, 1967, Jagnow, 1977, Middeldorp, 1996).
The degradation mechanism involves reductive dechlorination and dehydrohalogenation
pathways to produce less chlorinated cyclohexanes and chlorophenols, and finally gives
various tri-, di-, and monochlorobenzenes, and benzene as end products (Quintero, 2005).
Aerobic biodegradation has also been reported, with the data suggesting that lindane
could be cometabolized in the environment and, under certain conditions, could serve as
32
the sole source of carbon for (Sahu et al., 1990, Gupta et al., 2000). Biological methods
have shown the feasibility of decreasing the BOD, COD and TOC of wastewater to some
extent, and probably they are among the most inexpensive water treatment techniques
(Alinsafi et al., 2005). However, biological methods are inadequate for the treatment of
high molecular weight biorefractory compounds, since they are not easily degraded by
bacteria and they may also inhibit bacterial development (Georgiou et al., 2003).
1.4.1.3 Advanced oxidation processes (AOPs)
Compared to the processes using mere physical transfer, advanced oxidation
processes (AOPs) have merged to be promising alternatives, which successfully
transform hazardous organic pollutants into harmless end products. The concept of AOPs
was established by Glaze (Glaze, 1987), who defined AOPs as “processes involving the
generation of highly reactive oxidizing species capable of attacking and degrading
organic substances near ambient conditions of pressure and temperature”. Nowadays,
AOPs are considered as high efficiency physical-chemical processes capable of
producing deep changes in the chemical structure of the contaminants via the
participation of free radicals (Quiroz et al., 2011). The chemical reactions involved are
essentially the same as if the pollutants were otherwise slowly oxidized in the
environment, but the oxidation rate is billions of times faster in AOPs (Bolton, 2010).
AOPs are generally based on the use of in situ formed wide variety of highly
reactive free radicals, such as •OH, SO4•−, H•, •OOH, O2
•−, e−aq etc that can effectively
decompose almost all refractory organic pollutants without an additional separation step
(Lin et al., 1995, Anipsitakis and Dionysiou, 2004a, 2004b, Rodriguez et al., 2011 ).
Depending upon the source of the radical generation, various classes of AOPs have been
33
recognized. The most commonly employed AOPs include Fenton and Fenton-like
processes (Fenton, 1894, Matta, 2007), photo-Fenton and photo-Fenton-like reactions
(Bauer and Fallmann, 1997; Kang, 2000; Bandala, 2009), ozonation (Peyton and Glaze,
1988; von Gunten, 2003), direct UV photolysis (Kundu et al, 2005; Dantas, 2010),
UV/H2O2 photolysis (Wallington, 1988, Peternel, 2006), TiO2 photocatalysis (Carey et
al., 1976, Malato et al., 2002, Nakata and Fujishima, 2012), sonolysis (Bertelli and Selli,
2004; Vassilakis et al., 2004; Uddin and Hayashi, 2009), radiolysis (Getoff 1995; Cooper,
2003), electrolysis (Martinez-Huitle and Ferro 2006; Radjenović 2012) and reduction by
zero valent iron (ZVI) (Kim and Carraway 2000). A short description of the AOPs
employed for the treatment of water and wastewater organic pollutants is given below:
1.4.1.3.1 Fenton and photo-Fenton reactions
Among the established AOPs, Fenton and photo-Fenton processes are the most
widely studied classes of the reactions for the pollutant degradation, because of (i) easy
availability of Fenton’s reagents (ii) cost-effectiveness and (iii) high reactivity and non-
selectivity of the generated •OH towards most organic pollutants.
Fenton’s reagent comprises a homogeneous catalytic oxidation system consisting
of a mixture of hydrogen peroxide (H2O2) and iron (Fe2+). The ferrous ion (Fe2+) initiates
and catalyses decomposition of H2O2 resulting in the generation of hydroxyl radicals,
•OH (Fenton, 1894). The general reaction is:
Fe2+ + H2O2 → Fe3+ + •OH + OH− (1.1)
In photo-Fenton process in addition to the above reaction, the formation of •OH
also occurs by reactions (1.2) and (1.3) (Ho 1986; Kochany and Bolton, 1992):
H2O2 + hν → 2 •OH (1.2)
34
Fe3+ + H2O + hν → •OH + Fe2+ + H+ (1.3)
Nitoi and co-workers studied simultaneously the degradation of lindane and
mineralization of organic chlorine in aqueous solution by photo-Fenton process in batch
experiments (Nitoi et al., 2013). The degradation rate followed pseudo-first order kinetics
with respect to lindane and organic chlorine mineralization. Results of photo-Fenton
reactions assured total organic carbon (TOC) removal with 95% efficiency at 2 h
irradiation. Optimal experimental conditions for 99% removal of lindane at initial
concentration of 3.47 × 10−6 M were: pH = 3, [H2O2] = 29.41 × 10−3 M, [Fe2+] = 3.67 ×
10−3 M, and time = 1 h. The value of klindane higher than kCl− confirmed that chlorine
liberation did not take place simultaneously with the attack of •OH on lindane. Despite
many advantages, however, the requirement of low pH environment is the major
limitation to Fenton and photo-Fenton’s processes.
1.4.1.3.2 UV/H2O2 system
Hydrogen peroxide (H2O2) is one of the most efficient sources of •OH radical
known for long time, however, the rate of •OH generation is very slow and some
activation mean is needed in practical applications. The combination of UV/H2O2 is
widely applicable to wastewater treatment for destruction of wide range of toxic
pollutants (Wallington, 1988, Peternel, 2006).
Nienow and co-workers (2008) studied the oxidation of lindane in terms of
lindane degradation and release of chloride ions in the UV/H2O2 system. Results showed
that 90% of the lindane was destroyed in about 4 min under these conditions. In addition,
within 15 min, all chlorine atoms were converted to chloride ion, indicating that
chlorinated organic by-products do not accumulate in the reaction mixture. The presence
35
of humic acid (HA) and fulvic acid (FA) showed retarding effects on the degradation
process which can be considered as major limitation of the process, since these
compounds are commonly found in real water samples. Although the presence of HA and
FA does reduce the reaction rate during treatment, the rate constant in the presence of
these compounds remains significantly larger compared to direct photolysis or hydrolysis
reactions. They also measured the absolute rate constant for oxidation of lindane with
•OH radical. The results showed that lindane rapidly reacted with •OH and the maximum
reaction rate constant (9.7 × 10−3 s−1) were observed at pH 7 and initial H2O2
concentration of 1 mM. The •OH was generated by UV/H2O2 process, tetrachloroethene
(PCE) was chosen as reference compound and rate constant was determined using
competitive kinetics method.
Haag and Yao (1992) determined the rate constants of •OH with lindane molecule
by relative rate method, using tetrachloroethylene (TCE) and 1, 2-dibromo-3-
chloropropane (DBCP) as reference compounds. A variety of techniques, including
Fenton’s reaction and photo Fenton’s processes, were employed for generation of •OH
radical. The absolute rate constant, kabs (lindane) was found to be 1.1 x 109 M−1 s−1
(Fenton reactions) and 5.2 x 108 M−1 s−1 (photo-Fenton reactions) using TCE and DBCP,
respectively, as reference compounds (Haag and Yao, 1992).
1.4.1.3.3 Ozonation
Ozone is long been used for oxidation of many kinds of chemical substances
including toxic pollutants (Camel and Bermond, 1998, Javier Benitez et al., 2002). The
oxidation of organic pollutant by O3 can be achieved through either direct or indirect
pathway. In direct pathway, the organic compound is oxidized by O3 itself in acidic
36
media whereas indirect ozonation involves the degradation of organics through •OH
under basic conditions. Ozone in the gas phase and in solution absorbs ultraviolet
radiation with a maximum at 254 nm. In water-rich gas phase, the process involves
dissociation into an oxygen molecule and an oxygen atom in lD state. The latter may
react with H2O to produce two •OH via reactions (1.4) and (1.5) (Hoigné 1998):
O3 + hν → O2 + O (1D) (1.4)
O + H2O → 2 •OH (1.5)
In the aqueous phase, the radicals apparently combine in a solvent cage to yield
hydrogen peroxide (H2O2), which may also photolyze or combine with ozone through a
complex radical mechanism. Thus by combining UV radiations with O3, the oxidation
power of the system for organic pollutant degradation could be significantly enhanced.
Begum and Gautam (2012) studied the chemical oxidation of lindane with ozone
and developed a reaction kinetics and mechanism under various experimental conditions.
Optimization of parameters was done and ozone dose of 57 mg min−1 was chosen as
optimal for initial lindane concentration of 25.72 μM, while any further increase in ozone
dose had a diminishing effect on the removal efficiency. The pH of the solution was
found effective in influencing the extent of degradation and lindane removal rate was
favoured under alkaline conditions, plausibly due to higher rate of •OH generation.
Kinetics results showed that the degradation rate follows first-order kinetics with respect
to lindane concentration. The observed degradation rate constants (kobs) for initial lindane
concentrations of 17.5, 25.72 and 35.00 μM were 0.0243, 0.0333 and 0.056 min−1,
respectively.
37
1.4.1.3.4 Reduction by zero valent iron
Zero-valent iron (ZVI) comprises an emerging technology for the destruction of a
large variety of toxic organic pollutants (Agrawal and Tratnyek, 1995, Li et al., 2006).
Schlimm and Heitz (1996) reported dechlorination of lindane to benzene by various
transition metals, such as zero valent zinc, Fe/Cu, Al/Cu, Zn/Cu, and Mg/Cu systems.
Wang and co-workers (2009) studied the removal of lindane from water by granular zero-
valent iron under varying experimental conditions. The rate of the reaction was found to
vary with solution pH, temperature and iron dosage, and the reaction followed pseudo-
first-order kinetics with respect to concentration of lindane. The higher reaction
temperature, higher ZVI dosage and lower pH favoured the degradation reaction kinetics.
At the end of the reaction, lindane was converted to benzene and chlorobenzenes. Singh
and co-workers studied the efficiency of nZVI for the remediation of lindane
contaminated soil at different pH values. The reaction followed pseudo first order
kinetics leading to complete disappearance of lindane (initial concentration 10 μg g-1) in
24 hours at nZVI concentration of 1.6 g L-1. The system showed higher efficiency at
lower pH. Benzene was reported as the final degradation product of lindane under the
given conditions (Singh et al., 2011).
1.4.1.3.5 Electrolysis
Electrolysis is a versatile, non-selective and efficient technique employed for
destruction of organic pollutants in contaminated water (Martinez-Huitle and Ferro,
2006). The electrochemical methods for the destruction of POPs are mild and
environment-friendly and many types of reaction systems can be easily designed. The
rate of pollutant decomposition and the removal efficiency depend on the kind of
38
electrode material, electrolyte composition, pH etc (Comninellis 1994). Electrochemical
treatment is successfully applied for many kinds of toxic pollutants chlorinated organic
compounds, such as nitrophenol, PCPs and disinfection by-products (DBPs), antibiotics
and pharmaceutical compounds (Wei et al., 2011; Patel and Suresh, 2008; Radjenović et
al., 2012). Most of the investigators concluded that electrochemical reduction of lindane
is a six-electron process that produces benzene as the major product. Beland and co-
workers reported that lindane undergoes a one-step, six-electron reduction to afford
benzene as the final product at cathode (Beland et al., 1977).
1.4.1.3.6 Microwave irradiation
Microwave radiations can shorten the reaction times and increase the yield and
purity of the products compared with the conventional heating methods. When solvents
of high vapor pressures are employed in microwave (MW) irradiation treatment, there is
a risk of explosions. Thus, the so-called dry media technique (i.e. in the absence of
solvent) has been coupled to MW irradiation. The lack of use of organic solvents during
the organic reactions gives rise intrinsically to cleaner, and more efficient and economic
technology, increasing safety and decreasing the overall work needed for the process. In
many cases, higher amounts of reactants can be treated and there is possibility of acting
on the selectivity of the systems (Mingos and Baghurst, 1991).
1.4.1.3.7 Ionizing radiation
Ionizing radiation technology, an emerging AOP, characterized by the in situ
generation of highly oxidizing and reducing species (i.e., •OH and eaq−) via equation (1.6)
(Spinks and Woods, 1990), has recently gained much attention because of the high
efficiency, cost effectiveness and environmental compatibility (Bhatti et al., 2014).
39
Consequently, extensive research has been carried in the field of gamma irradiation for
the destruction of toxic organic compounds including pesticides, herbicides,
polychlorinated biphenyls (PCBs), methyl tert-butyl ether (MTBE), pharmaceuticals and
dyes (Cooper et al., 2009, Basfar et al., 2007, Csay et al., 2012, Getoff, N., 1986, 1995,
Mincher et al., 1991, Rauf and Ashraf, 2009, Tahri et al., 2010). The end product of
gamma radiation process is mostly carbon dioxide or other simple biodegradable and
harmless end products.
H2O ---^-^--> •
OH(2.8) + eaq
−
(2.7) + •
H(0.6) + H3O+
(3.2) + H2O2(0.72) +
H2(0.45) + OHaq
−
(0.5) (1.6)
where the numbers in parenthesis denote the radiation yield or G-values at 10−7 s after
irradiation. G-values are the number of species produced or destroyed per 100 eV of
energy absorbed and are a means of expressing the efficiency of the radiolysis (Spinks
and Woods, 1990).
Hydrated electron (eaq−) is the most powerful reductant in aqueous solution (E˚ =
− 2.9 V) that reacts rapidly with many species having more reduction potentials (Buxton
et al., 1988). An enhanced reactivity is observed when organic molecules contain electron
withdrawing constituent such as halogen atoms, subsequently leading to the
dechlorination of the organic compound (Buxton et al., 1988, Spinks and Woods, 1990).
Despite high affinity of the hydrated electron for reacting with chlorinated compounds,
there is very limited study on the degradation of lindane, a typical chlorinated pesticide,
by gamma radiation based AOPs (Mincher et al., 1991, Mohamed et al., 2009).
40
1.4.1.3.8 TiO2 photocatalysis
Titanium dioxide (TiO2) is one of the most promising photocatalysts because of
its high efficiency, low cost, chemical inertness and photostability in nature (Hoffmann et
al., 1995, Wilcoxon and Thurston, 1998). TiO2 photocatalysis is regarded as a promising
technology for the treatment of water and wastewater organic pollutant (Lagunas-Allué et
al., 2012, Malato et al., 2001, Ollis and Al-Ekabi, 1993). Around 40 years ago, Carey and
co-workers reported the photocatalytic degradation of biphenyl and chlorobiphenyls in
the presence of TiO2 (Carey et al., 1976). Since Carey’s invention, TiO2 photocatalysis
was effectively applied for the destruction of large number of toxic compounds including
POPs (Hoffmann et al., 1995).
Several researchers have studied TiO2 photocatalytic degradation of lindane under
UV light (Dionysiou et al., 2000; Senthilnathan and Philip, 2010). Zaleska and co-
workers reported 50% of lindane removal ([lindane]0 = 0.137 mM) in150 min, using TiO2
(anatase) supported on glass hollow microspheres (Zaleska et al., 2000). Dionysiou and
co-workers reported 63% lindane removal in 170 min (([lindane]0 = 16.0 μM), using
TiO2 immobilized on a continuous flow rotating disc (Dionysiou et al., 2000).
Recent advances in the field of TiO2 photocatalysis introduce non-metal doping into
TiO2 that remarkably increases researchers’ interest because of a potential of the doped
TiO2 material to utilize low energy photon (visible light) for excitation of electron
(Hoffmann et al., 1995, Asahi et al., 2001). As a result, the restriction of UV light
radiation for band gap excitation in TiO2 photocatalysis is removed, and consequently,
this achievement has opened up various novel applications of TiO2, particularly in the
sense of utilizing the most abundant solar light radiations (comprising ~ 45% visible
41
light) (Hoffmann et al., 1995, Chatterjee and Dasgupta, 2005). Developing new doped-
TiO2 photocatalyst is a rapidly growing research area and many studies have reported the
synthesis, fabrication and characterization of the doped-TiO2 photocatalyst (Pelaez et al.,
2012). The potential application of visible light assisted doped-TiO2 photocatalysis for
environmental remediation has been reported previously (Pelaez et al., 2012, Chatterjee
and Dasgupta, 2005).
S-doping effectively achieves narrowing of the band gap of TiO2 or introduces
localized mid-gap states in the band gap of TiO2 in a similar way as N-doping (Asahi et
al., 2001). Sulfur appears to be one of promising non-metals for the synthesis of visible
light-activated photocatalysts to decompose different contaminants (Umebayashi et al.,
2002). Sulfur was successfully inserted into TiO2 lattice via substitution of either oxygen
(O) or titanium (Ti) (Tachikawa et al., 2004). Umebayashi et al. reported that mixing of
the S 3p states with the valence band (VB) caused an increase in the VB width, with a
subsequent band gap narrowing in sulfur-doped TiO2 (S-TiO2), thereby shifting
considerably the absorption edge to lower energy region (Umebayashi et al., 2002). Our
research group has recently synthesized a nanostructured S-TiO2 photocatalyst through a
sol–gel method, which is cost-effective and easy to operate (Han et al., 2011). Sol–gel
method allows facile synthesis of photocatalysts with a high purity, stability and
uniformity in their structural and physicochemical properties, at ambient conditions
(Mutuma et al., 2015).
The photocatalytic activity of TiO2-based photocatalysts for degrading organic
pollutants can be increased in the presence of inorganic oxidants such as hydrogen
peroxide (H2O2), peroxymonosulfate (PMS, HSO5−) or persulfate (PS, S2O8
2−) (Andersen
42
et al., 2013, Chen et al., 2012, Malato et al., 1998). Compared to H2O2 or PS, PMS was
found to be the most suitable oxidant for degradation of 2,4-dichlorophenol, Acid Orange
7 and other organic contaminants (Chen et al., 2012, Malato et al., 1998).
1.4.1.3.9 Sulfate radical based-AOPs
Compared to hydroxyl radical based AOPs (•OH-based AOPs) (represented by
ozonation, UV/H2O2, photo-Fenton process and TiO2 photocatalysis), sulfate radical
based AOPs (SO4•−-based AOPs) are relatively a new group of treatment technologies,
which require more investigations on their potential applicability in treating the
contaminated water (Watts and Teel, 2006). SO4•− can be generated by the activation of
persulfate (PS) and peroxymonosulfate (PMS) with transition metals, elevated
temperature or pH, and/or UV irradiation (Anipsitakis and Dionysiou, 2004a, 2004b).
SO4•−, with standard reduction potential, E˚= 2.5-3.1 V, is a stronger oxidant than •OH
(i.e., E˚= 1.8-2.7 V), and is capable of rapid mineralization of recalcitrant pollutants at
neutral pH. The high oxidation efficiency of SO4•−, high aqueous solubility, high stability
with slow rate of the oxidants’ consumption, economically cheap and environmental
friendly nature make this technology an attractive option in wastewater treatment and
other environmental applications in recent years. Anipsitakis and Dionysiou (2003)
reported that SO4•− is more efficient than •OH for the transformation of 2, 4-
dichlorophenol, atrazine and naphthalene under certain conditions. Previous research
studies have demonstrated that SO4•−-based AOPs employing PS as a precursor oxidant
can effectively degrade lindane in water and soil (Cao et al., 2008, Usman et al., 2014).
However, no research studies have been found in the literature about the degradation of
lindane by SO4•−-based AOPs employing peroxymonosulfate (PMS).
43
Peroxymonosulfate (available as a triple potassium salt with a commercial name of
Oxone®, 2KHSO5·KHSO4·K2SO4) is a highly versatile and an environmentally friendly
oxidant (Kennedy and Stock, 1960). It has received great attention and application in
water disinfection and decontamination (Anipsitakis et al., 2008). UV light and Fe2+ were
chosen in this study to activate PMS, a process that can generate both SO4•− and •OH as
shown below in reactions (1.7) and (1.8) (Anipsitakis and Dionysiou, 2004a, 2004b).
HSO5− + hν → SO4
•− + •OH (Φ = 1.04) (1.7)
Fe2+ + HSO5− → Fe3+ + SO4
•− + OH− (k = 3.0 × 104 M−1 s−1) (1.8)
1.5 Aims and objectives of the Present Work
The main objective of this research work is to investigate the efficiency of several
emerging AOPs, i.e., gamma radiation, sulfate radical based-AOPs, and non-
metal doped TiO2 photocatalysis for the degradation of lindane in water.
The efficiency of Fe2+/HSO5− based AOPs for the degradation of lindane will be
investigated under the influence of fluorescence light and UV light irradiation.
The effects of water quality and process parameters, such as solution pH, initial
concentrations of lindane, Fe2+ and HSO5−, presence of inorganic ions and natural
organic matters, will be studied.
The mineralization of lindane and decomposition of HSO5− under various AOPs
will be assessed.
The second-order rate constant of lindane with •OH, SO4•− and eaq
−, generated in
the studied AOPs will be determined, using pulse radiolysis techniques or
competition kinetics model.
44
Mechanism of lindane degradation in the selected AOPs will be investigated,
based on the reaction by-products, identified via GC/MS analysis.
Dechlorination and mineralization efficiencies of various AOPs for degradation of
lindane will be studied, to assess the extent of water detoxification.
A nano-structured non-metal doped S-TiO2 photocatalyst (e.g., S-TiO2) will be
synthesized by a sol-gel method using a self-assembly technique, and its
photocatalytic activity for the degradation of lindane under solar and visible light
irradiation will be investigated.
The effect of HSO5− on visible and solar light-assisted S-TiO2 photocatalysis of
lindane will be particularly studied.
The degradation of trichlorobenzene (TCB), a typical reaction by-product of
lindane, will also be investigated.
Finally, the assessment of lindane residues in the surface water samples, in
different regions of district Swabi, Khyber Pakhtoonkhwa (Pakistan) will be
carried out.
45
2. EXPERIMENTAL
Different types of materials, chemicals and instruments used during the present study
along with procedure adopted and calibration of instruments are explained in this chapter.
2.1 Materials
Lindane (1,2,3,4,5,6-Hexachlorocyclohexane, γ-isomer; 97% purity) was obtained
from Sigma Aldrich (UK). Hydrogen peroxide (50%, v/v) and ferrous sulfate (98%) used
for photo-Fenton reagents, were purchased from Fisher Scientific (USA). Potassium
peroxymonosulfate (PMS), available with commercial name oxone®
(2KHSO5.KHSO4.K2SO4, 95%) and sodium persulfate (Na2S2O8, 98%) were purchased
from Sigma Aldrich. Inorganic salts e.g., sodium nitrate (NaNO3), sodium nitrite
(NaNO2), sodium sulfate (Na2SO4), sodium bicarbonate (NaHCO3), potassium chloride
(KCl) and potassium carbonate (K2CO3) were of analytical reagent grade quality and
obtained from Fisher Scientific. Organic solvents and radical scavengers, such as ethanol,
methanol, acetone, acetonitrile, tert-butanol (t-BuOH) and iso-propanol (i-PrOH) were all
HPLC grade and purchased from Merck (Germany). Humic acid (HA) standard was
obtained from the International Humic Substances Society (IHSS, University of
Minnesota, St. Paul, MN, USA) and used as representative of natural organic matters
(NOMs). Sodium hydroxide and perchloric acid, used for pH adjustments, were
purchased from Riedel-de Haën (Germany). Phosphate buffer solutions (pH 4.0 and pH
7.0) were used for pH meter calibration and were purchased from Scharlau (Spain).
Polyoxyethylene (80) sorbitan monooleate (Tween 80), isopropyl alcohol (i-PrOH,
99.7%), titanium (IV) isopropoxide (TTIP, 97%) and sulfuric acid (H2SO4, 95–98%)
were used as precursors in the synthesis of TiO2 and S-TiO2 films and obtained from
46
Sigma–Aldrich (USA). Oxalic, tartaric, acetic and formic acids were obtained from Fluka
and these acids were used as standard compounds for identification of reaction
intermediates and products. Ultra pure nitrogen (carrier gas for GC, purity 99.999%) and
ultra pure Helium (make up gas for GC, purity 99.999%) were obtained from Wright
Brothers Inc, PA (USA). Nitrous oxide (Medical grade) and oxygen gas (Commercial
grade) used as dissolved gases were purchased locally in Peshawar. Ultra pure water
(resistivity of 18.2 MΩ.cm) was obtained from Milli-Q coupled with MILLIPORE Elix®
5 UV water purification system.
All the reagents were used as received without further purification.
2.2 Sample Collection
Surface water samples were collected from 18 different places in district Swabi. The
sampling site is shown in Figure 2.1. The Swabi district is located on the bank of the
Indus River near Islamabad. Swabi district comprises a vast cultivation region covering a
total area of about 1,550 square kilometers and having a population of around 1,027,000.
The major sources of irrigation water in Swabi district are the two main canals, i.e. the
upper Swat canal and the Stefa canal. For drinking purposes and other house hold
applications, people usually take water from the wells and tube wells, in district Swabi.
The samples were collected from the agriculture fields as well as from the canals. The
samples SS1, SS2 (Shewa), SS4, SS5 (Kalu Khan) and SS8 and SS10 (Firdous abad)
were taken from canal water whereas the remaining samples were collected from
agriculture fields. The samples were stored in clean-washed plastic bottles and were
analyzed in the Radiation and Environmental Chemistry laboratories (RECLs) of the
National Centre of Excellence in Physical Chemistry, University of Peshawar. Prior to
47
SPME technique, the samples were filtered through 0.45 μm filter paper in order to
remove any type of particulate matter, if present.
Swabi
Shewa
Ismaila
Dobian
Kalu Khan
Yar Hussain
Dagi
Yaqubi
Sudher
Adina
Terwatu
Sabdar Abad
SS1
SS2
SS3
SS4
SS5
SS6SS7
SS8
SS9
SS10
SS11
SS12
SS13
SS14SS15SS16
SS17
SS18
Sard Cheena
Ayuab Khan Kalay
Firdous Abad
Figure 2.1. Sampling cite of district Swabi, KPK, Pakistan.
48
2.3 Preparation of Solutions
Stock solution of lindane (17.15 μM) was prepared by stirring the required weight
of solid lindane in water for 24 hours at room temperature (T = 25 ± 1 ˚C). Standard
solutions of lindane were prepared by dilution of the stock solution to the desired level.
PMS (10 mM) and FeSO4.7H2O (5mM) stock solutions were prepared and stored at 4 °C.
The pH of FeSO4.7H2O solution was set at 3.0 using 0.01M H2SO4. All the solutions
were prepared in ultra pure Milli-Q grade water.
pH of the solutions was measured by a HANNA HI 9124 (USA) pH meter using
glass electrode calibrated with standard buffers at pH 4.0 and 7.0. The calibrated pH
meter was used for adjusting the pH of the test solutions.
2.4 Extraction Technique
Solid Phase Micro Extraction (SPME) technique was employed for extraction of
lindane from aqueous solution. The SPME fibre needle (DVB/CAR/PMDS type;
Supelco, USA) consisted of a 10 mm long and 100 μm thick fused silica fibers, coated
with 95 μm thick polydimethylsiloxane (PMDS). SPME technique is based on the
equilibration of the analyte between an aqueous phase and an organic polymer coated
onto a fused silica fiber. On injection in GC column, the analyte is thermally desorbed
into the inlet and sent by mobile phase into the detector device. The sample injection was
performed using a CTC Analytics CombiPAL autosampler connected with the GC. In
some cases, SPME manual syringe (Supelco, Bellefonte, USA) was used for the injection
purpose. The time of adsorption for lindane onto the SPME fibre was 2 min, while
desorption time inside the inlet was 1 min.
49
2.5 Reactor Design
2.5.1 Gamma rays reactor
Ionizing radiation experiments were performed using a Cobalt-60 gamma-rays
source (model Issledovatel (USSR)) available in the Food and Soil Division (FSD) of the
Nuclear Institute for Food and Agriculture (NIFA), Peshawar (Pakistan). The source
consists of twelve cylindrical Co-60 rods, which are arranged in a circle (internal
diameter 0.2 m). The height of each rod is 2.1 x 10–2 m and diameter is 1.1 x 10–2 m. The
gamma radiation source is protected externally by using a thick lead shield. The picture
of the source is shown in Figure 2.2.
Figure 2.2. Cobalt-60 gamma rays source at NIFA.
50
2.5.2 UV reactor
UV degradation experiments were performed in a bench scale photoreactor
consisting of a Pyrex glass Petri dish (100 mm diameter x 15 mm height) with a quartz
cover. A 10 mL of lindane solution (C0 = 3.43 μM) was taken in the reactor vessel and it
was irradiated from the top with two 15 W low pressure mercury lamps (UV-C lamp
from Cole-Parmer, USA) that emitted light primarily at a wavelength of 253.7 nm. The
reactor vessel was held on the top of a magnetic stir plate. A Teflon coated magnetic stir
bar was used to mix the solution during irradiation. The reactor vessel was sealed with
Parafilm and cooled with a fan to prevent evaporation and maintain a constant
temperature (T = 25 ± 1 °C). The mercury lamps were turned on 30 minutes prior to
experiments for uniformity of the UV fluence. At selected times after initiating
photolysis; a 150 μL sample was removed from the reaction vessel and transferred to a
200 μL glass insert held inside the HPLC vial. Any radicals within the sample were
immediately quenched by adding 50 μL methanol and samples were analyzed on Agilent
6890 GC interfaced to an Agilent 5975 mass selective detector. Control experiments were
performed on the solutions that were (i) not photolysed and (ii) without oxidant.
2.5.3 UV-Vis reactor
A borosilicate glass dish (dia. 100 mm) was used as a photoreactor for
photocatalytic experiments. The sulfur doped TiO2 (S-TiO2) films were placed in the
photoreactor containing lindane solution at desired concentrations. The films were
washed with MilliQ water and then dried under an infrared lamp before the
photocatalytic experiments. Two 15 W fluorescent lamps (Cole-Parmer) were used as a
visible light source. For visible light irradiation, a UV block filter (UV420, Opticology)
51
was mounted under the light source and the light intensity determined by a broadband
radiant power meter (Newport Corporation) was found to be 9.05 × 10−5W cm−2. The
output spectrum after the filter has been reported by Han and coworkers (Han et al.,
2011). A UV-Vis light irradiation assembly is shown in Figure 2.3. A 0.2 mL sample was
withdrawn from the reaction mixture at selected times (i.e. 0, 1, 2, 4, and 6 h). The
concentration of lindane in the samples was quantified using Gas chromatography-mass
spectrometry (Agilent Series 6890) with a HP-5MS capillary column (30 m × 0.25 mm ×
0.25 μm). The photocatalytic experiments were performed in an Advanced
SterilChemgardIII ClassII (Baker) biological cabinet for health and safety reasons.
Figure 2.3. Batch reactor used for UV-Vis radiation treatment.
52
2.5.4 Solar reactor
Simulated solar light experiments were performed in a bench scale photoreactor
consisting of a Pyrex glass Petri dish (100 mm diameter x 15 mm height) with a quartz
cover. The reactor vessel was sealed with Parafilm and cooled with a fan to prevent
evaporation and maintain a constant temperature (T = 27 ± 1 ˚C). A 10 mL of lindane
solution was taken in the reactor vessel and it was irradiated from the top with 300 W
Xenon lamp (67005, Newport, Oriel Instruments) which provided a spatially averaged
light intensity of 47.1 mWcm−2 obtained from a broadband radiometer (Newport
Corporation). The broad spectrum of the lamp light was transformed to mimicking solar
light radiation by introducing appropriate filters. The first filter, an Air Mass 1.5 Global
Filter (Newport Corporation), attenuated the irradiation to simulate sunlight
corresponding to a 48.2º angle of incidence. The second filter was an FSQ-KG5 filter
(Newport Corporation), which is a heat absorbing filter. The output spectrum of the filter
has been reported by J. Andersen and coworkers, demonstrating adequate simulation of
solar radiation (Andersen et al., 2013).
2.5.5 Tube-light reactor
Tube-light radiation experiments were conducted under the typical room light
conditions that existed in the laboratory having dimensions: width × length × height = 15
× 20 × 15 = 4500 feet3 and equipped with sixteen ordinary Philips lightening tubes. A
typical reactor for the tube-light experiments consisted of a 40 mL clear amber glass with
PTFE/Silicone screw caps. A 10 mL of lindane solution was transferred to the reactor
vessel after addition of the desired amount of oxidant (PMS) and catalyst (Fe2+). The
reaction mixture inside the reactor vessel was kept on constant mixing in a rotator (at 50
53
cycle/min) to ensure the homogeneity of the solution. The experiments were performed at
room temperature (T = 23±2 °C). At selected time intervals, 150 μL samples were
removed and transferred to a 200 μL glass insert kept inside the HPLC vials and
quenched with 50 μL of methanol.
2.5.6 Dark reactor
The same experimental conditions as mentioned for tube-light experiments
(section 2.4.5) also existed here, except that the tube-lights were turned off during the
reaction period and the clear amber vials were replaced with dark glass vials in case of
dark experiments. After removal from the reaction vessel, the samples inside the HPLC
vials were covered by aluminium foil to protect from the effect of light before the
analysis is done.
2.6 Calibration of Radiation Sources
2.6.1 Calibration of irradiation source
A Fricke dosimetry solution was used for calibration of the irradiation source
(Sehested, 1970). Fricke dosimetry solution was prepared by dissolving 22.2 mL of 98%
H2SO4, 0.278 gm of FeSO4.7H2O and 0.058 gm of NaCl in one litre of milli-Q water.
NaCl was added to remove the effects of dissolved organic impurities, if present in the
solution (Spinks and Woods, 1990).
The solution was purged with oxygen gas (O2) for 20 min to make it O2-saturated
prior to irradiation. The main reaction of Fricke dosimeter is oxidation of ferrous ion
(Fe2+) to ferric ion (Fe3+) under gamma irradiation in the presence of oxygen ((Spinks and
Woods, 1990). A 15 mL Fricke dosimetry solution in 20 mL Pyrex glass tube was kept
inside the gamma radiation field at ambient temperature (25±2 °C). After selected time
54
intervals, the samples were removed and change in absorbance of the solution was
measured using UV / Vis spectrophotometer at wavelength of 304 nm using unirradiated
solution in the reference beam. All the experiments were carried out in triplicate and a
mean value for the change in absorbance (∆OD) was obtained. The change in absorbance
(∆OD) was plotted versus irradiation time (see typical calibration plot in Figure 2.4) and
slopes of the plots ((∆OD/min) were calculated. The dose rate (D•) was determined by
using equation 2.1 (Sehested, 1970);
A
3+
N × ΔOD/min × 100D = eV/g
ε×ρ×1000×G(Fe )
(2.1)
D• = Absorbed dose rate
NA = Avogadro number (6.022 × 1023)
(∆OD/min) = Difference in absorbance between the irradiated and non-irradiated samples
per min (slope of the calibration plots).
x = molar extinction co-efficient of ferric ion at 304 nm 2205 M−1cm−1 .
= Density of the Fricke dosimeteric solution (1.024 g/cm3)
Radiation yield ( G -value) of Fe3+ for gamma radiolysis of Fricke solution = 15.6
By putting the values of NA, (∆OD/min), xε , ρ , and G(Fe3+) in equation (2.1), we get
23
3
6.0223 10 100 ΔOD/minD eV/g
2205 1.024 10 15.6
x
(2.2)
D• = 1.7099 x 1018 × (∆OD/min) eV/g (2.3)
Since 1 eV/g = 1.6022 x 10−14 rad
So, D• = 1.7099 × 1018 × 1.6022 × 10−14 × ∆OD rad.
D• = 2.7396 × 104 × ∆OD rad min−1 (2.4)
55
Since 1 rad. = 10−2 Gy
D• = 2.7396 × 102 × ∆OD Gy min−1 (2.5)
∆OD = slope (min−1)
∆OD/min = slope
Putting the value of ∆OD in equation (2.5), the values of D• under different experimental
conditions were determined. The dose rate inside the cylindrical sample compartment of
gamma ray source can be reduced by using different thickness metallic containers as
given below.
a. Open container
The highest dose rate can be obtained in open container (using no metallic
shielding inside sample compartment). An aqueous acidic solution of ferrous sulfate was
irradiated in an open container of the Co-60 source and the slope obtained was
determined, as shown in Figure 2.4. The value of slope (0.0168) was put into equation
(2.5) and dose rate was determined as shown below
D• = 2.7396 × 102 × 0.0168 Gy/min = 4.603 Gy/min
D• = 4.603 × 60 Gy/hr = 276 Gy/hr (2.6)
b. Brass container
In this case, Fricke dosimetry solution was irradiated in a brass container instead
of the open container. Figure 2.4 shows the plot and value of the slope (0.0121) was used
in equation (2.5) to determine the dose rate.
D• = 2.7396 × 102 × 0.0121 Gy/min = 3.315 Gy/min
D• = 3.315 × 60 Gy/hr = 199 Gy/hr (2.7)
c. Brass and iron container
56
By irradiating solution of ferrous sulfate in an iron container adjusted inside a
brass container, the slope obtained is shown in Figure 2.4. The value of the slope
(0.0055) was inserted in equation (2.5) and the dose rate was determined as below.
D• = 2.7396 × 102 × 0.0055 Gy/min = 1.507 Gy/min
D• = 1.507 × 60 Gy/hr = 90 Gy/hr (2.8)
2.6.2 Calibration of UV radiation source
Three different calibration methods; iodide/iodate actinometry (Rahn, 1997),
ferrioxalate actinometry (Murov et al., 1993; Goldstein and Rabani, 2008), and a
calibrated digital radiometer (Model IL 1700, XRD (XRL) 140T254 low profile
germicidal probe, International Light, Co., Newburyport, MA) were employed to
determine the average UV fluence rate (mW cm−2) of the UV radiation source.
The aqueous solution used for iodide/iodate actinometery consisted of 0.6 M KI
and 0.1 M KIO3 in a 0.01 M sodium tetraborate decahydrate (Na2B4O7.10H2O) buffer
solution. The iodide/iodate actinometric experiments were performed within four hours
after the solutions were prepared. In case of iodide/iodate actinometery, the photoproduct
is tri iodide ion (I3) (see reaction 2.9) that is highly photosensitive in the UV range and
can be accurately quantified at = 352 nm (with molar extinction coefficient of 352 =
27,600 M−1 cm−1). The quantum yield of this actinometer is = 0.73 at 254 nm (Rahn,
1997).
The overall photochemical reaction is:
8 I + IO3 + 3 H2O + h 3 I3
+ 6 OH (2.9)
57
The absorbance of the actinometric solution was measured with spectrophotometer soon
after preparation at wavelengths of 300 nm and 352 nm. The absorbance of the
actinometric solution measured at 352 nm before irradiation was used as a blank
(A352(blank)). The solution was then irradiated in a 10 mL Petri dish with UV-C light
source for time intervals of 5, 10, 15, 20, and 25 min in triplicate and absorbance was
measured after each reading (A352(sample)).
The following formula was used for calculation of UV fluence rate.
)s()cm(
)]blank()sample([969.23
2
352352
imeExposure tArea
AAE
V (mL) (mW cm2) (2.10)
Where E: light intensity,
Area: area of the Petri dish in cm2,
Exposure time: the time of sample illumination in s, and
V: the volume of sample solution in mL.
The above equation can be written into the following form as:
A352(sample) − A352(blank) = [(Area(cm2)/(23.969 V (mL)) ) E] Exposure
time(s) (2.11)
In the present study the volume was 10 mL and area of the Petri dish was 19.64 cm2,
thus:
A352(sample) − A352(blank) = (0.0819 E) Exposure time(s) (2.12)
A plot of [A352(sample) − A352(blank)] versus Exposure time (s) gave a straight
line with slope equal to 0.0084, as shown in Figure 2.5. Dividing the slope by 0.0819, we
can get the light intensity in mW cm–2, which was 0.10 mW cm–2..
E = 0.0084/0.0819 = 0.10 mW cm–2.
58
The source was also calibrated with ferrioxalate actinometry and calibrated digital
radiometer, whose details has been given elsewhere in literature (Murov et al., 1993;
Goldstein and Rabani, 2008). The results of the three measurements were consistent with
each other. The calibrated radiometer was used to check the fluence rate of the UV source
every day before use.
2.7 Qualitative/Quantitative Analysis of Lindane and other Products
2.7.1 Gas chromatography with electron capture detector (GC/ECD)
The degradation of lindane was monitored by gas chromatography (GC, Agilent
6890N) equipped with HP-5 capillary column (30 m × 0.32 mm × 0.25 μm, J&W
Scientific) using a Ni63 electron captured detector (ECD). The conditions used for the
analysis of lindane by the GC/ECD are presented in Table 2.1. Lindane gave a sharp peak
at a retention time of 9.033 min, under the given experimental conditions. A typical
chromatogram of lindane on GC/ECD system is given in Figure 2.6.
Quantification of lindane was carried out by peak area measurements based on
external standards calibration plot. A typical calibration plot for lindane on GC/ECD is
given in Figure 2.7, with linear correlation coefficient (R2) of 0.9995. The limit of
detection (LOD) at signal-to-noise ratio of 3 (S/N = 3) was 0.008 μM and the limit of
quantification (LOQ) at signal-to-noise ratio of 10 (S/N = 10) was 0.037 μM. All the
analyses were performed in triplicate and the mean value was used for results.
2.7.2 Gas chromatography-mass spectrometry (GC/MS)
In order to identify the by-products generated during the degradation of lindane,
GC/MS analysis was performed employing a HP 6890 series GC equipped with a HP
5973 mass spectrometry. Separation of the sample components was achieved using HP-
59
5MS capillary column (30 m × 0.25 mm × 0.25 μm). The conditions used for the analysis
of lindane on the GC/MS system are presented in Table 2.2. Mass spectra were obtained
by the electron-impact mode (EI) at 70 eV, using scan mode (50-800 m/z) under the
following conditions: pressure: 7.63 psi, purge flow: 26.5 mL.min-1, purge time: 1 min.
GC/MS information was matched with NIST mass spectra library for identification of
unknown compounds.
2.7.3 Ion chromatography (IC)
The chloride ion (Cl-) produced during degradation of lindane was analyzed with
Metrohm, 800 series Ion Chromatograph (IC) equipped with anion self-regenerating
suppressor, a dual-piston pump, a DS6 conductivity detector and an IonPac A Supp 4
separating column (250 mm × 4 mm). An IonPac AG19 guard column (250 mm × 4 mm)
was inserted before separating column for entrapping the impurities. A mixture of 1.8
mM sodium carbonate and 1.8 mM sodium bicarbonate solution (50/50 by volume) was
used as eluent, while 50 mM sulfuric acid was added as a regenerating agent. The flow
rate was 1 mL min-1 and the injection volume was 500 μL. The eluents were sonicated for
15 min and filtered through 0.45 μm cellulose acetate filters (Sartorius, Ministar) before
use, to prevent the effects of air bubbles and other impurities.
The same IC system was used for determination of aliphatic acids, as degradation
by-products such as oxalic, acetic and formic acids, but the gradient was changed (5 mM
from 0 to 10 min and then increasing to 10 mM from 10 to 40 min). Before injection in
IC, the sample was filtered through 0.45 μm cellulose acetate filters (Sartorius, Ministar)
for removal of impurities.
60
2.7.4 High performance liquid chromatography (HPLC)
The concentration of 2-chlorophenol (used as reference compound in the
competition kinetics study) was monitored by high performance liquid chromatography
(HPLC) using an Agilent 1200 series equipped with a UV detector. The separation was
achieved on reversed phase Eclipse XDB-C18 column (4.6 mm × 150 mm, 5 μm). The
column was thermostated at 30 ºC. The injection volume was 20 μL. The column was
eluted with a mixture of water: acetonitrile at 50:50 (v/v) with a flow rate of 1.0 mL/min.
2.7.5 Total organic carbon (TOC) analyzer
Total organic carbon (TOC) of the treated and untreated samples was monitored
using a Shimadzu VCSH-TOC analyzer equipped with an ASI-V autosampler.
Calibration of the TOC analyzer was performed with potassium hydrogen phthalate and
sodium hydrogen carbonate, used as standards for measuring total carbon and inorganic
carbon, respectively. The difference between total carbon and inorganic carbon gives
TOC of the sample. When the lindane degradation experiments were conducted at
concentration of 3.43 μM, the TOC experiments were performed at concentration of 17.5
μM, as the lower concentration of lindane cannot work with TOC.
2.7.6 UV spectrophotometer
The concentration of PMS residue was determined using HP 8452A UV–vis
spectrophotometer, according to a reported method (Liang et al., 2008). The
spectrophotometer covered a wavelength range from 190 to 820 nm and was equipped
with a diode array detector and a deuterium lamp. PMS concentrations were determined
by comparing absorbances to a standard calibration plot, constructed from data obtained
with known concentration of PMS processed under the same experimental conditions. In
61
the PMS concentrations range of 0 - 2.0 mM, a plot of absorbance Vs. PMS concentration
generated a straight line with R2 = 0.990. A typical calibration plot is shown in Figure
2.8.
2.8 Synthesis of Sulfur Doped TiO2 Photocatalyst
Sulfur doped TiO2 photocatalyst was synthesized via a modified sol-gel method
explained elsewhere in literature and briefly described here (Han et al., 2011). A nonionic
surfactant polyoxyethylene (80) sorbitan monooleate (Tween 80, Sigma–Aldrich) was
used as a pore directing agent. The surfactant (Tween 80) was dissolved in iso-propyl
alcohol (i-PrOH, 99.8%, Pharmco) and titanium (IV) isopropoxide (TTIP, 97%, Sigma–
Aldrich) was added as an alkoxide precursor. Finally, sulfuric acid (H2SO4, 95–98%,
Pharmco) was added as a sulfur precursor and reagent for in situ formation of water. The
final solution obtained was somewhat yellow like, transparent, homogeneous and stable
after stirring for 24 h at room temperature. The Tween 80:i-PrOH:TTIP:H2SO4 molar
ratio employed for the preparation of the sol was 1:45:1:1. As reference, TiO2 films were
synthesized following the same procedure but the surfactant was excluded and sulfuric
acid was replaced with acetic acid at the same molar ratio.
The resulting sol–gel was immobilized onto plain borosilicate glass micro slides
(Gold Seal, 75 mm × 25 mm) by dip-coating method. Before dip coating, the slide
surface was rinsed with Milli Q water followed by ethanol and dried under an infrared
lamp. A self-made dip-coating apparatus with a speed controller device was used to dip
in and pull out the substrate from the sol at a withdrawal rate of 12.5 ± 0.3 cm min−1 for a
final effective surface area of 10 cm2. After coating, the film was dried with an infrared
lamp for 20 min and calcined in a multi segment programmable furnace (Paragon Model
62
HT-22-D, Thermcraft Inc., Winston-Salem, NC) where the temperature was increased at
a ramp rate of 900 ºC h−1 to 400 ˚C, maintained for 30 min to remove all organics and
then allowed to cool down naturally. The dip coating and calcination process were
repeated five times to obtain films with 5 layers (thickness: 1.02 ± 0.02 μm, total mass:
4.51 ± 0.18 mg). In addition, sulfur doped TiO2 particles from thick films were prepared
to characterize the porosity and crystal structure, since it is very difficult to collect
samples from the glass substrates due to extremely small amount of TiO2 in the thin
films. For sulfur doped TiO2 particle characterization, the sol was dried on borosilicate
glass dishes at 90 ºC for 6 h and then heat-treated at 400 ºC for 12 h using a multi-
segment programmable high temperature furnace (Paragon Model HT-22-D, Thermcraft
Inc., Winston-Salem, NC) in order to remove all organics completely, resulting in the
formation of thick films. The TiO2 particles were scratched up from thick films and
grinded. Reference TiO2 films and particles were prepared following the same
preparation and calcination processes.
63
Irradiation time (min)
2 4 6 8 10 12 14 16 18 20 22
Ch
an
ge
in
ab
so
rban
ce
at
304 n
m (
a.u
.)
0.00
0.05
0.10
0.15
0.20
0.25
0.30
0.35
0.40
Open container, R2 = 0.9965
Brass containor, R2 = 0.9968
Brass + Iron containor, R2 = 0.9963
Figure 2.4. Typical calibration plots of gamma irradiation source using Fricke dosimetry
solution kept in different containers (a.u = arbitrary units).
Time of UV photolysis (s)
0 20 40 60 80 100 120 140 160 180 200
Absorb
ance (
a.u
.)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
Figure 2.5. A typical calibration plot for UV radiation source at λmax = 352 nm, by
iodide/iodate actinometry.
64
Figure 2.6. A typical chromatogram of lindane ([C]0 = 10 µgL−1) using GC/ECD system
(The GC/ECD conditions are given in Table 2.1).
Concentration of lindane (M)
0 5 10 15 20 25
Pe
ak a
rea (
a.u
.)
0
200
400
600
800
1000
1200
1400
1600
1800
R2 = 0.9995
Figure 2.7. A typical calibration plot for lindane measurement on GC/ECD system.
65
Concentration of calibration solution (PMS, mM)
0.0 0.5 1.0 1.5 2.0 2.5
Absorb
ance (
a.u
.)
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
Figure 2.8. A typical calibration plot for PMS measurement on the UV-Vis
spectrophotometer at λmax = 352 nm.
66
Table 2.1 Operating conditions for GC/ECD analysis of lindane.
Items Conditions
Injector split-state splitless
Temperature (°C) 210 °C
SPME extraction time (min) 2
SPME desorption time (min) 1
Oven Temperature program 50 °C (4 min) to 150 °C at 5 °C /min,
150 °C to 250 °C (5 min) at 8 °C /min
Carrier gas Gas Nitrogen
Flow rate (mL/min) 1.5
Detector µECD
Table 2.2 Operating conditions for GC/MS analysis of lindane.
Items Conditions
Injector split-state splitless
Temperature (°C) 210 °C
SPME extraction time (min) 2
SPME desorption time (min) 1
Oven Temperature program 50 °C (4 min) to 150 °C at 5 °C /min,
150 °C to 250 °C (5 min) at 8 °C /min
Carrier gas Gas Helium
Flow rate (mL/min) 1.5
Detector GC/MS
Ion source temperature 230 °C
Quadrapole temperatures 150 °C
Electron energy 70 eV
Scan range (m/z) 50-450
67
3. RESULTS AND DISCUSION
Lindane is highly toxic and persistence pesticide and incidence of lindane
contaminations have been found in water and soil samples in different parts of the world.
Residue of lindane in the field water samples of district Swabi, which is agriculturally
one of the most developed areas of the Khyber Pakhtoonkhwa (KPK), Pakistan, has been
investigated.
3.1 Determination of Lindane in Field Water Samples of District Swabi, KP, Pakistan
3.1.1 Optimization of the GC/ECD method for lindane analysis
First of all, a specific method was developed for analysis of lindane in water on
the GC/ECD system using SPME fibre. The optimized method parameters were given in
Section 2.3. The linearity of the detector response was studied in lindane concentration
range of 0.02 to 20.00 µg/L. Within the given concentration range, the detector gave a
linear response with R2 = 0.999. The calibration plot is shown in Figure 2.6 (chapter 2).
The limit of detection (LOD) determined at signal to noise ratio (S/N) of 3 was found to
be 0.008 μg/L and the limit of quantification (LOQ) determined at signal to noise ratio of
10 was found to be 0.037 μg/L. The LOD, LOQ and R2 value of the GC/ECD are given
in Table 3.1.
3.1.2 Precision, accuracy, reproducibility and relative recoveries of the method
The efficiency of the given method was checked by measuring the precision,
accuracy and reproducibility of the system under the optimized conditions and the results
are presented in Table 3.2. The accuracy of the optimized method was calculated by
using equation (3.1) (Whitmire et al., 2010):
68
Average measured concentrationAccuracy = × 100
nominal concentration (3.1)
The relative recoveries were also determined by using equation (3.1), but in this
case field water was used as solvent for the preparation of lindane solution rather than
Milli-Q water, which was used in case of accuracy measurement. Precision (closeness of
agreement between the replicate independent test results) was measured in terms of
relative standard deviation (% RSD). It can be seen from Table 3.2 that very precise,
highly accurate and reproducible results were obtained under both intra-day and inter-day
conditions. The relative recoveries of the optimized method are shown in Table 3.3.
69
Table 3.1. Performance of SPME followed by GC/ECD for determination of lindane
Analyte Equation Correlation coefficient
(R2)
LOD (µg/L) LOQ (µg/L)
Lindane y = 67.02x + 2.75 0.9995 0.008 ± 0.0003 0.037 ± 0.002
70
Table. 3.2. Intra-day and inter-day precision, accuracy and reproducibility of the optimized method
Analyte Nominal
concentration
(μg/L)
Intra-day response Inter-day response
measured
concentration
(Mean ± SD)
Precision
(%RSD)
Accuracy
(%)
measured
concentration
(Mean ± SD)
Precision
(%RSD)
Accuracy
(%)
Lindane
in water
2.5 2.64 ± 0.27 10.29 105 2.37 ± 0.28 11.91 94.78
5.0 4.82 ± 0.25 5.15 96 5.03 ± 0.26 5.12 100.55
10.0 9.20 ± 0.71 7.68 92 9.27 ± 0.39 4.21 92.70
71
Table. 3.3. Comparison of relative recoveries (Accuracy) and relative standard deviation (Precision) of lindane by SPME-assisted
GC/µECD method in different field water samples.
Lindane
conc.
(μg/L)
SS1 SS3 SS6
SS11
SS14
SS15
Relative
recovery
(%)
R.S.D.
(%)
Relative
recovery
(%)
R.S.D.
(%)
Relative
recovery
(%)
R.S.D.
(%)
Relative
recovery
(%)
R.S.D.
(%)
Relative
recovery
(%)
R.S.D.
(%)
Relative
recovery
(%)
R.S.D.
(%)
2.5 88.18 8.98 110.57 7.87 88.58 13.18 114 2.64 103.37 16.04 99 17.48
5.0 98.46 9.16 101.05 11.28 95.66 14.84 103 8.99 96.56 3.11 92 7.77
10.0 83.31 9.78 88.40 8.09 99.69 7.14 99 2.56 88.05 5.17 100 5.31
72
3.2 Application of the Optimized GC/ECD Method to Real Water Samples
The validated method was applied for analysis of 18 field water samples collected
from different places of Swabi district. The results obtained are given in Table 3.4. It can
be seen from Table 3.4 that out of eighteen (18) samples analyzed, thirteen (13) were
found to be contaminated with lindane, while in remaining five (5) samples, no lindane
was detected. Of the thirteen contaminated samples, seven samples were found to contain
lindane concentration beyond the maximum acceptable level (MAL) for a single pesticide
in surface water i.e., 1.0 µg/L (Lopez-Blanco et al., 2002), while the remaining six
samples had lindane concentration below the MAL. It can also be seen from Table 3.4
that canal water (i.e. Samples SS1, SS2 (Shewa), SS4, SS5 (Kalu Khan) and SS8 and
SS10 (Firdous abad) contains more amount of lindane pesticide as compared to the field
water. A comprehensive detail about the sample information is provided in section 2.2
and Figure 2.1 (chapter 2). The possible reason is that pesticide contaminated water of
various agriculture fields is continuously added which can increase the concentration of
lindane in the canal water. The presence of high concentrations of lindane in the water
samples of district Swabi is mainly due to the use of these pesticides for various
agriculture purposes in this area. The high concentration of lindane (above the maximum
acceptable level) presents high risks for various pesticide related diseases in the
inhabitants of this region.
After the first step of evaluating the residues of lindane in some of the field water
samples of district Swabi, the next step of the current work was to develop a chemically
advanced and environmental friendly technique for removal of lindane from aqueous
solution. Gamma radiation-induced degradation of lindane was studied under various
73
experimental conditions and the effect of different parameters on the degradation kinetics
was determined. To avoid the effect of the matrixes found in field water, the degradation
experiments were carried out in ultra pure Milli-Q water. However, the effect of natural
organic matter (NOM) and inorganic salts (present in field or surface water) on the
removal efficiency was determined by mixing these substances into the Milli-Q water.
Finally, the absolute rate constant of hydroxyl radical with lindane was determined by
using competition kinetics, while the absolute rate constant of hydrated electron with
lindane was determined by pulse radiolysis technique. In addition to the gamma radiation
technology, removal of lindane from water by several other innovative AOPs, such as
TiO2 photocatalysis, SO4•− radical-based Fenton-like and photo-Fenton-like processes
were also investigated.
74
Table 3.4. Distribution of lindane in the field water samples of district Swabi.
Sites Concentration (µg/L) Sites Concentration (µg/L)
SS1 3.31 SS10 4.03
SS2 3.77 SS11 ND
SS3 ND SS12 0.40
SS4 4.13 SS13 ND
SS5 3.54 SS14 0.06
SS6 ND SS15 ND
SS7 0.17 SS16 1.35
SS8 1.08 SS17 0.44
SS9 0.09 SS18 0.11
ND: Not detected
.
75
3.3 Gamma Radiation-induced Degradation of Lindane in Water
An aqueous lindane solution (C0 = 3.43 µM) was irradiated by gamma rays and
the concentration ratio (concentration at time ‘t’/ initial concentration = C/C0) was plotted
against absorbed dose. The results of the gamma radiolytic decay of lindane are shown in
Figure 3.1. As can be seen, the concentration of lindane decreases with increase of
gamma radiation doses which ultimately led to 97% lindane removal at an absorbed dose
of 2000 Gy.
Radiolysis of water results in the generation of highly reactive radical species,
such as e−aq, •OH and H• (equation (1.6) that attack and destroy the organic pollutants
(Spinks and Woods, 1990). Figure 3.1 shows that the lindane degradation rate is fast in
the beginning, while it slows down with increasing accumulated radiation dose. This
behavior can be explained on the basis of the competition for the pollutant (lindane)
between the reactive radicals, which increases with increasing radiation dose, thus
resulting in decreased removal efficiency (Yu et al., 2008). Another possible explanation
is the competition of the intermediate by-products with the lindane molecules for the
reactive radicals which increase with the increasing accumulated radiation dose. Such a
decrease in the degradation rate with the increasing radiation dose was observed in the
radiolytic degradation of several other pollutants as well (Lin et al., 1995; Basfar et al.,
2005a; Yu et al., 2008). The radical–radical recombination reactions, including e−aq, •OH
and H• that increase with the increasing radiation dose rate (Lin et al., 1995) can be
another possible reason for the decreasing removal rate at increasing accumulated
radiation dose. Some of the major reactions along with bimolecular reaction rate
76
constants (mol−1 s−1) that can take place in the gamma irradiated aqueous solution are
given below (Buxton et al., 1988, Spinks and Woods, 1990):
•OH + eaq− → HO− (k = 3.0 × 1010 M−1 s−1) (3.2)
•OH + •H → H2O (k = 7.0 × 109 M−1 s−1) (3.3)
•OH + •OH → H2O2 (k = 5.5 × 1010 M−1 s−1) (3.4)
eaq− + eaq
− → H2 + 2HO− (k = 1.1 × 1010 M−1 s−1) (3.5)
•OH + H2O2 → HO2• + H2O, (k= 2.7 × 109 M−1 s−1) (3.6)
•OH + HO2• → H2O + O2, (k = 1 × 1010 M−1 s−1) (3.7)
•OH + HO2− → H2O + O2
•−, (k= 7.5 × 109 M−1 s−1) (3.8)
3.3.1 Kinetic Studies of the Gamma Radiation-induced Degradation of Lindane
The exponential decrease in lindane concentration with the increasing radiation
dose suggested pseudo-first order kinetics behavior for lindane decay, expressed by
equation (3.9) (Spinks and Woods, 1990).
C = C0 exp (−kD) (3.9)
The modified version of equation (3.9) is given below:
−ln[C/C0] = k.D (3.10)
where C0 is the initial concentration of lindane; C is the residual concentration of
lindane at any radiation dose; D is the absorbed dose; and k is the dose constant in
reciprocal dose units (Gy˗1). When −ln[C/C0] is plotted against the absorbed dose (D), a
straight line is observed whose slope is equal to the dose constant, k. The value of dose
constant, k can be affected by several experimental conditions, such as initial pollutant
concentration, solution pH, the addition of radical scavengers and the molecular structure
of the compound (Mincher et al., 2002; Lee and Jeong, 2009).
77
3.3.1.1 The effect of initial solute concentration
The effect of initial lindane concentration on the gamma radiation-induced
degradation of lindane was studied in batch kinetic experiments. Initial lindane
concentrations of 0.343, 0.686, 1.715 and 3.434 μM, were irradiated for absorbed doses
up to 1000 Gy and the lindane decomposition results are shown in Figure 3.2a.
The normalized lindane concentration (C/C0) decreased with increasing absorbed
dose. For absorbed dose of 1000 Gy, the removal efficiencies for initial aqueous lindane
concentrations of 0.343, 0.686, 1.715 and 3.434 μM were 95, 94, 91 and 83%,
respectively. The observed degradation dose constants of lindane at different initial
concentrations are shown in Figure 3.2b and Table 3.5. The dose constant increased with
decreasing initial concentrations of lindane. An increase in the degradation dose constant
with decreasing initial concentrations of the pollutants was also observed during the
gamma radiolysis of 2,4,6-trinitrotoluene (Lee and Lee, 2005), cefaclor (Yu et al., 2008)
and alachlor (Choi et al., 2010).
78
Absorbed dose (Gy)
0 500 1000 1500 2000 2500
C/C
0 (
lin
da
ne
)
0.0
0.2
0.4
0.6
0.8
1.0
Absoseorbed dose (Gy)
0 500 1000 1500 2000 2500
-ln(C
/C0)
0
1
2
3
4
R2= 0.9994
Figure 3.1. Radiation-induced degradation of lindane in N2-saturated aqueous solution.
Experimental conditions: [lindane]0 = 3.43 µM, pH = 6.8. In the insert is shown
the plots of −ln(C/C0) Vs absorbed dose for determining pseudo-first order
kinetics.
Table 3.5. Change in dose constant (k) with increasing the initial concentration of
lindane.
[Lindane]0 (µM) Dose constant, k (Gy−1) R2
0.343 0.0029 0.9958
0.686 0.0027 0.9954
1.715 0.0023 0.9988
3.434 0.0017 0.9895
79
(a)
Absrobed dose (Gy)
0 200 400 600 800 1000 1200
C/C
0 (
lind
an
e)
0.0
0.2
0.4
0.6
0.8
1.0
C0 = 3.434 M
C0 = 1.715 M
C0 = 0.694 M
C0 = 0.343 M
(b)
Absrobed dose (Gy)
0 200 400 600 800 1000 1200
-ln(C
/C0)
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
C0 = 0.343 M, R2 = 0.9958
C0 = 0.694 M, R2 = 0.9955
C0 = 1.715 M, R2 = 0.9988
C0 = 3.434 M, R2 = 0.9896
Figure 3.2. (a) Removal of lindane at different initial concentration Vs irradiation doses
and (b) dependency of the initial concentration on the dose constant. Experimental
conditions: pH = 6.8, N2-saturated.
80
3.3.1.2 Effect of pH
The efficiency of gamma irradiation process is greatly associated with the
solution pH. The results of the gamma radiolytic degradation of lindane under three
different pH conditions (4.0, 8.0 and 6.8) are shown in Figure 3.3a. The results show that
the lindane removal efficiency is maximum at neutral pH, while it decreased under both
acidic and basic conditions. At an absorbed dose of 2000 Gy, the degradation efficiency
of lindane was 50, 97, and 80% when the solution pH was 4.0, 6.8 and 8.0, respectively.
The removal efficiencies of the radiation-induced degradation processes are dependent on
the type and concentration of active species. The concentrations of the reactive species of
water radiolysis vary with the solution pH (Spinks and Woods, 1990). In acidic medium,
the hydrated electron (eaq−) reacts with H+ (equation (3.11) (Zhang et al., 2007). In
alkaline solution, •OH can react with −OH (equation (3.12)), thereby decreasing the
concentration of •OH (Buxton et al., 1988, Guo et al., 2009). The equations (3.11) and
(3.12) are likely to lower the concentration of hydrated electron and •OH radicals
resulting in reduced lindane removal efficiency under the acidic and basic conditions.
eaq− + H+ → H• k = 2.3 × 1010 M−1 s−1 (3.11)
•OH + HO− → H2O + O− k = 1.3 × 1010 M−1 s−1 (3.12)
Lindane removal efficiency at different pH values fitted pseudo-first order kinetic model.
At solution pH of 4.0, 6.8 and 8.0, the observed degradation dose constants are 3.56 ×
10−4, 1.71 ×10−3 and 8.21 × 10−4 Gy−1, respectively. The observed degradation dose
constants of lindane obtained from the plots of −ln(C/C0) vs. absorbed dose at different
initial pH are shown in Figure 3.3b. It can be seen that the degradation dose constant
decreased both under the acidic and basic pH conditions. The observed decrease in
81
degradation efficiency at acidic pH is most likely due to the scavenging effects of eaq− by
the H+ ion under such conditions (Spinks and Woods, 1990, Huang et al., 2009).
Similarly, the standard reduction potential of •OH is significantly reduced at higher pH
and this may be another factor leading to a decreased removal efficiency at higher pH.
82
(a)
Absorbed dose (Gy)
0 500 1000 1500 2000 2500
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0
pH = 4.0
pH = 8.0
pH = 6.8
(b)
Absorbed dose (Gy)
500 1000 1500 2000 2500
-ln
(C/C
0)
0
1
2
3
4
pH = 6.8, R2 = 0.9853
pH = 8.0, R2 = 0.9755
pH = 4.0, R2 = 0.9555
Figure 3.3. (a) Removal of lindane at different initial pH Vs irradiation doses, and (b)
Dependency of the initial pH on the dose constant. Experimental conditions:
[lindane]0 = 3.43 µM, N2-saturated.
83
3.3.2 Scavenging effects on gamma radiation-induced degradation of aqueous lindane
Several kinds of reactions may be involved in the gamma radiolytic degradation
of lindane in aqueous solution. Lindane may be degraded by reaction with reducing
species such as, aqueous electron (eaq−) and hydrogen radical (H•), or it may be oxidized
by reaction with hydroxyl radicals (•OH). The radicals produced in the gamma radiolysis
of water can be selectively scavenged by the addition of certain chemicals or gases that
allow measurement of the role of a single radical with the substrate. In order to elucidate
the role of a single reactive radical and to find out the overall mechanism of degradation,
the effect of dissolved gases (such as nitrogen, air and nitrous oxide) on the lindane
degradation was studied. The degradation studies were performed under a set of four
different experimental conditions that included:
1. N2-saturated solution (control),
2. N2-saturated solution containing 60 mM i-PrOH (reductive conditions),
3. N2O-saturated solution (oxidative conditions) and
4. Air-saturated solution.
Figure 3.4a illustrates the ratio of lindane concentration (C/C0) as a function of
irradiation dose, while Figure 3.4b shows the observed degradation dose constants under
the above mentioned conditions. The results indicated that lindane degradation efficiency
was maximum in the N2-saturated solution (control condition), while it was minimum in
the N2O-saturated solution (oxidative conditions). The degradation efficiency had
intermediate value in the aerated solution and N2-saturated solution containing i-PrOH.
84
3.3.2.1 Radiolysis of lindane in N2-saturated solution (control experiments):
In N2-saturated solutions, all of the originally produced reactive radicals i.e.
hydrated electrons, hydroxyl radical and H-atoms (equation (1.6)) are present and able to
react with lindane pesticide. It can be seen from Figure 3.4a and 3.4b that the highest
degradation efficiency was observed under N2-saturated conditions, corresponding to
97% lindane removal at an absorbed dose of 2000 Gy. Under N2-saturated conditions, the
stoichiometric ratio of the reactive radicals present in the aqueous solution is 46:44:10 for
the •OH, e-aq and H• radicals, respectively (Wasiewicz et al., 2006). The highest
degradation efficiency under the N2-saturated conditions revealed that all the three major
species of water radiolysis i.e. eaq−, •OH and H• radicals can play significant role in the
degradation of lindane.
3.3.2.2 Radiolysis of lindane in aerated solution (natural condition):
Under aerated conditions, the dissolved oxygen in water (ca. 2.5 × 10−4 M at 25
˚C) is able to scavenge a large fraction of the hydrated electrons (eaq−) and almost all of
the hydrogen atoms (equations (3.13) and (3.14)) in the solution (Buxton et al., 1988). In
aerated solutions, there are 46% •OH and 54% O2•− species reacting with substrate
(Wasiewicz et al., 2006).
eaq− + O2 → O2
•− (k = 1.9 × 1010 M−1 s−1) (3.13)
H• + O2 → H+ + O2− (k = 1.2 × 1010 M−1 s−1) (3.14)
3.3.2.3 Radiolysis of lindane in N2-saturated 60 M i-PrOH solution (reductive
conditions):
For selective monitoring of hydrated electrons, experiments were performed in a
N2-saturated 60 M i-PrOH solution. The function of the N2 pre-saturation is to remove
85
the dissolved oxygen (O2) from the solution. The dissolved oxygen acts as a strong
scavenger of eaq−, as shown in equation (3.14). i-PrOH scavenges •OH and H• to form the
relatively inert radical as shown in equations (3.15) and (3.16) (Buxton et al., 1988).
Figure 3.4a shows that the presence of 60 mM i-PrOH had only a small negative effect on
the degradation efficiency of lindane. These results revealed that •OH and H• radicals
have minor contribution in the degradation of lindane.
i-PrOH + •OH → (CH3)2•COH + H2O (k = 1.9 × 109 M−1 s−1) (3.15)
i-PrOH + H• → (CH3)2•COH + H2 (k = 7.4 × 107 M−1 s−1) (3.16)
3.3.2.4 Radiolysis of lindane in N2O-saturated solution (oxidative conditions):
The role of hydroxyl radicals (•OH) was determined by pre-saturating the lindane
solution with N2O gas that quantitatively converts the hydrated electrons to hydroxyl
radical (equation (3.17)) (Spinks and Woods, 1990);
eaq− + N2O + H2O → N2 + OH− + •OH (k = 9.0 × 109 M−1 s−1) (3.17)
Under the N2O-saturated conditions there is 90% •OH and 10% H•, while no
hydrated electrons exist in the solution. Figure 3.4a shows that the lindane degradation
efficiency was strongly reduced in the N2O-saturated solution. These results revealed that
the hydroxyl radical, •OH participated only slightly in the degradation of lindane and
major contribution was from reaction of eaq− with lindane.
From the graph, it appears that for 2000 Gy of irradiation, about 20% degradation
is from •OH radicals, 60% from eaq− and about 10% from H• radicals.
86
(a)
Absorbed dose (Gy)
0 500 1000 1500 2000 2500
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0N2O-satutrated
Aerated
N2+ 60 mM i-PrOH
N2-sturated
(b)
Absorbed dose (Gy)
0 500 1000 1500 2000 2500
-ln(C
/C0)
0
1
2
3
4
N2-saturated
N2+ 60mM i-PrOH
Aerated
N2O-saturated
, R2 = 0.9955
, R2 = 0.9958
R2 = 0.9984
R2 = 0.9893
Fig. 3.4.(a) Radiation-induced degradation of aqueous lindane in (i) Aerated solution;
(ii) N2-saturated solution; (iii) N2O-saturated solution; (iv) N2-saturated solution
containing 60 mM i-PrOH. (b) Dependency of the radical scavengers on the dose
constant. Experimental conditions: [lindane]0 = 3.43 µM, pH = 6.8.
87
3.3.3 Role of individual reactive species in lindane degradation
In order to investigate the role of individual reactive species (i.e., eaq‒, •OH and H•
radical) towards lindane degradation, the gradation experiments were performed under
the following conditions:
1. N2-saturated solution with no scavenger (scavenger free),
2. N2-saturated solution containing 60 mM i-PrOH
2. N2-saturated solution containing 60 mM t-BuOH
In the scavenger free solution, all the three species i.e., eaq‒, •OH and H• are operative.
In the i-PrOH containing solution, •OH and H• radicals are scavenged thus prevailing
condition for eaq− only, while t-BuOH containing solution selectively removes •OH
radicals, prevailing condition for eaq− and H•. Figure 3.5a represents the ratio of lindane
concentration (C/C0) as a function of irradiation dose, while Figure 3.5b shows the
observed degradation dose constants under the given experimental conditions.
The observed dose constant (k) in the given experimental conditions were calculated
from the plots of – ln(C/C0) versus absorbed dose (Figure 3.5b) and the calculated values
are given below (Table 3.6):
kno scavenger = 1.76 × 10‒3 Gy‒1
kt-BuOH = 1.47 × 10‒3 Gy‒1
ki-PrOH = 1.18 × 10‒3 Gy‒1
From the above mentioned values of k, the observed dose constant ratio of eaq‒, •OH
and H• can be calculated as:
ke‒aq : k•OH : kH•
ki-PrOH : (kno scavenger ‒ kt-BuOH) : (kt-BuOH ‒ ki-PrOH)
88
1.18 × 10‒3 Gy‒1 : (1.76 ‒ 1.47) × 10‒3 Gy‒1 : (1.47 ‒ 1.18) × 10‒3
Gy‒1
1.18 × 10‒3 Gy‒1 : 0.29 × 10‒3 Gy‒1 : 0.29 × 10‒3 Gy‒1
4 : 1 : 1
The ratio of k for eaq‒, •OH and H• showed that eaq
‒ play major role, while •OH and H•
play minor role in the gamma radiolytic lindane degradation. The increased reactivity of
eaq‒ in terms of lindane removal was also observed when the lindane degradation was
carried out in the presence of various radical scavengers.
The same experimental data could also be used to determine the quantum efficiency
(η) of each reactive radical with respect to degradation of lindane. By definition, the
quantum efficiency is “the number of molecules decomposed by a reactive species” (Liu
et al., 2005). Thus, the quantum efficiency for hydrated electrons (ηeaq‒) can be given as:
-
aq
-
aq
Total number of lindane molecules decomposed by e
total number of e producedaqe (3.18)
The G-value of eaq‒ (number of eaq
‒ produced per 100 eV of radiation energy
absorbed) is used to calculate the total number of eaq‒ produced during irradiation process
whereas the number of lindane molecules decomposed is calculated from the change in
molar concentration multiplied by Avogadro’s number. Since the G-value for eaq‒ is 2.7
(Spinks and Woods, 1990), the total number of eaq‒ produced during 1000 Gy (1 Gy =
6.24 × 1018 eV) irradiation will be:
18
206.24 10 2.71000 1.68 10
100
eV speciesGy
Gy eV
89
Therefore;
6 23
PrOH A
- 20
aq
10 6.02 10ΔC N0.0101
total number of e 10
i
aqe
(3.19)
where ΔCi-PrOH is the change in lindane concentration for 1000 Gy of radiation dose when
60 mM i-PrOH was used as radical scavenger.
Considering 2.8 and 0.6 as G-values for •OH and H• (Spinks and Woods, 1990), the
total number of •OH and H• produced during 1000 Gy energy absorbed will be 1.75 ×
1020 and 3.74 × 1019, respectively. Therefore, the quantum efficiencies for •OH and H•
can be calculated as:
6 23
No scavenger BuOH A
• 20
10 6.02 10ΔC ΔC N0.0092
total number of OH 10
t
(3.20)
-6 23
BuOH PrOH A
• 19
2.4 × 10 6.02 × 10ΔC ΔC N0.0386
total number of H 3.74 × 10
t i
(3.21)
Where ΔCN0 scavenger and ΔCt-BuOH represent change in lindane concentration for 1000
Gy of radiation dose when 60 mM t-BuOH and no radical scavenger are used,
respectively.
The results obtained revealed that the quantum efficiency of each reactive species is
far less than unity. It means that only a small fraction of the reactive species of the water
radiolysis is involved in lindane degradation, while most part of these reactive species is
wasted. This can be explained on the basis of two plausible reasons. Firstly, the various
reactive species of the water radiolysis react with each other, thus reducing the active
concentrations of these species than the original concentrations (Lin et al., 1995). Species
90
with low G value will have low degree of self recombination reactions and the resulting
high quantum efficiency as compared to the species with high G value. The self
recombination reactions of these reactive species are shown in reactions (3.2) – (3.8).
Secondly, the various intermediate by-products of lindane degradation may compete with
lindane for the reactive radicals which could possibly result in low quantum efficiency of
these species for lindane degradation (Lin et al., 1995; Basfar et al., 2005b; Yu et al.,
2008). The quantum efficiency ratio for eaq‒, •OH and H• may be expressed as:
ηeaq‒ : η•OH : η•H = 0.0101 : 0.0092 : 0.0386 = 1 : 1 : 4
91
Table 3.6. The dose constants of hydrated electron (ke‒aq), hydroxyl radical (k•OH) and the
overall degradation dose constant (ke‒aq,•OH,H•), G-value (Species/100 eV), %
removal and D0.5 of lindane at 500 Gy.
________________________________________________________________________
Type of reaction G-value Removal (%) k (Gy−1) D0.5 (Gy) D0.9 (Gy)
keaq−•
OH,H• 0.0431 65 1.77 x 10−3 393 1310
keaq− 0.0298 45 1.14 × 10‒3 608 2019
k•OH 0.0073 11 2.24 × 10‒4 3094 10279
92
(a)
Absorbed dose (Gy)
0 500 1000 1500 2000
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0
i-PrOH
t-BuOH
No scavenger
(b)
Absorbed dose (Gy)
0 500 1000 1500 2000
-lin
(C/C
0)
0
1
2
3
4No scavenger
t-BuOH
i-PrOH
Figure. 3.5. (a) Radiation-induced degradation of aqueous lindane in (i) N2-saturated
solution; (ii) N2-saturated + 60 mM i-PrOH, (iii) N2-saturated + 60 mM t-BuOH
(b) dependency of 60 mM i-PrOH and t-BuOH on the dose constant.
Experimental conditions: [lindane]0 = 3.43 µM, pH = 6.8.
93
3.3.4 Dechlorination studies of lindane
In addition to the studies of lindane degradation by gamma irradiation, studies
concerning its dechlorination were also conducted under the same experimental
conditions. The dechlorination studies were based upon the concentration of chloride ion
(Cl−) released during the gamma irradiation of lindane solution. The results of the Cl−
release with the increasing radiation dose are given in Figure 3.6. As can be seen from the
Figure 3.6, the concentration of Cl− increased with increasing radiation dose and reached
12.6 μM (61% of 3.43 × 6 = 20.58 µM Cl−) at an absorbed dose of 2000 Gy,
corresponding to 97% lindane degradation. The results showed that the rate of
dechlorination is high in the beginning but it slowed down with the passage of time. The
enhanced dechlorination efficiency in the beginning is due to greater activity of the
reactive species at start that decreased with time due to their reaction with the
intermediates of lindane degradation. The slower dechlorination rate at later stage can
also be attributed to the lower remaining concentration of lindane in solution. The lower
dechlorination rate can also be attributed to the formation of compounds with low
chlorine content that show slower dechlorination behavior compared to compounds with
more chlorine content (Buxton et al., 1988). Similarly, stable intermediates can be
formed which can resist dechlorination. Such a dechlorination trend is comparable to that
observed in the radiolytic dechlorination of several other chlorinated organic compounds,
such as 2-chlorophenol, chloroacetic acid and chloroform (Taghipour and Evans, 1997).
Further increasing the radiation dose up to 4000 Gy, the dechlorination efficiency
reached 88%, while complete disappearance of lindane occurred at radiation dose of 2620
Gy (data not shown). It is also possible that some even more stable intermediates, like
94
chlorinated organic acids and aldehydes may be formed that can be degraded at still
higher radiation doses. A slight difference between the theoretical and experimental
values may be due to experimental and analytical errors.
Nevertheless, the results revealed that lindane readily undergoes dechlorination at
mild gamma radiation doses. Thus, the dechlorination of lindane mainly occurs due to
reaction of the hydrated electrons with lindane. The dechlorination from vicinal carbons
as well as dehydrochlorination reaction introduces unsaturated bonds in the organic
molecules. The resulting unsaturated molecule is generally more susceptible to oxidation
via •OH attack.
From the results of the scavenging gases, it is clear that the lindane dechlorination
followed similar path as observed for lindane degradation. Under the effect of various
radical scavengers, the efficiency of dechlorination was decreased in the following order:
N2-saturated > Air-saturated > N2O-saturated solutions. Such a dechlorination trend can
be explained on the basis of reactivity of reactive radicals. The hydrated electron is
highly reactive in the N2-saturated solution, while it is totally absent from the N2O-
saturated solution.
3.3.5 Effect of common inorganic salts on lindane degradation
Na2CO3, NaHCO3, NaNO3, NaCl and NaNO2 are among the inorganic anions that
are commonly found in natural water resources and are likely to affect the efficiency of
the degradation process. Figure 3.7 shows the effect of 10−3 mol L−1 Na2CO3, NaHCO3,
NaNO3, NaCl and NaNO2 on lindane degradation by gamma-rays irradiation. The results
showed that the degradation efficiency is influenced by the addition of these ions. As
shown in Figure 3.7, at a given dose, the reduction efficiency of lindane was somewhat
95
higher in the presence of sodium carbonate and sodium bicarbonate than that in the
absence of these salts. Since CO32− could react with H3O+, the inhibition of H3O+ on eaq
−
was reduced and the concentration of eaq− produced by gamma-ray irradiation increased
(Schmelling et al., 1998). The lindane can also be degraded by CO3•− radicals, produced
in equation 3.23. On the other hand, the addition of NaNO3 and NaNO2 resulted in
reducing the removal efficiency since eaq− was quickly scavenged by these ions (Singh
and Kremers, 2002) and •OH was scavenged by NaNO2 (Zhang et al., 2007). The
scavenging of eaq− and •OH by NO3
−, NO2− and Cl− ions is shown in reactions 3.22-3.26
(Spinks and Woods, 1990, Buxton et al., 1988). A positive influence of CO32−-ions on the
gamma radiolytic degradation of pollutants is consistent from other literature reports also
(Zhang et al., 2007). Similarly, a negative effect of NaNO3 and NaNO2 additives on the
pollutants degradation has also been reported in literature (Mucka et al., 2003, Zhang et
al., 2007)
•OH + CO32− → CO3
•−+ OH− (k = 3.39 × 108 M−1 s−1) (3.22)
NO2‒ + e‒
aq → NO22‒ (k = 3.5 × 109 M−1 s−1) (3.23)
NO2‒ + •OH → NO2
+ OH‒ (k = 1.0 × 1010 M−1 s−1) (3.24)
NO3‒ + e‒
aq → NO32− (k = 9.7 × 109 M−1 s−1) (3.25)
Cl‒ + •OH → ClOH•˗ (k = 4.3 × 109 M−1 s−1) (3.26)
96
Absorbed dose (Gy)
0 500 1000 1500 2000 2500
Conce
ntr
ation o
f lin
dane (
M)
0
1
2
3
4
Conce
ntr
ation o
f C
l- (
M)
0
2
4
6
8
10
12
14
[lindane]
[Cl-]
Figure 3.6. Dechlorination and degradation studies of lindane versus radiation dose.
Experimental conditions: [lindane]0 = 3.43 µM, pH = 6.8, N2-saturated.
Absorbed dose (Gy)
0 500 1000 1500 2000 2500
C/C
0 (
lin
da
ne
)
0.0
0.2
0.4
0.6
0.8
1.0
NO2
-
NO3-
Cl-
No additive (Control)
HCO3
-
CO3
2-
Fig. 3.7. Effect of CO32−, HCO3
−, Cl˗, NO3− and NO2
− ions on lindane degradation by
gamma-ray irradiation. Experimental conditions: [lindane]0 = 3.43 µM, [CO32−]0
= [HCO3−]0 = [Cl˗]0 = [NO3
−]0 = [NO2−]0 = 1mM, N2-saturated.
97
3.3.6 Effect of H2O2 on lindane degradation
H2O2 is an inorganic oxide that is commonly used for advance oxidation treatment
of water. It may directly react with pollutant but most often it generates highly reactive
hydroxyl radicals on gamma radiolysis (reaction 3.27). However, it has high second-order
rate constant for reaction with hydrated electron and hydrogen atom and may negatively
affect those processes which are controlled by those species. The reaction of H2O2 with
hydrated electron and hydrogen atom is shown by reactions (3.28) and (3.29),
respectively (Buxton et al., 1988). When used in excess amount, H2O2 acts as an •OH
radical scavenger by reactions (3.30) (Spinks and Woods, 1990)
2 2 2 raysH O OH (3.27)
H2O2 + eaq‒ → •OH + OH‒ (k = 1.1 × 1010 M−1 s−1) (3.28)
H2O2 + H• → •OH + H2O (k = 9.00 × 107 M−1 s−1) (3.29)
H2O2 + •OH → H2O + HO2• (k = 2.7 × 107 M−1 s−1) (3.30)
Figure 3.8 shows the effect of three different concentration of H2O2 on the
gamma-radiation induced degradation of lindane in water. As can be seen, the lindane
removal efficiency was greatly reduced in the presence of H2O2. From the negative effect
of H2O2 on the lindane removal efficiency, it is evident that hydrated electron is the major
species involved in the gamma radiolytic lindane decay.
3.3.7 Effect of natural organic matter (NOM) and synthetic organic pollutants
Humic acids (HAs) are yellow- to black-colored macromolecular substances that
constitute a considerable fraction of natural organic matter (NOM) in surface waters. The
presence of NOMs generally has an effect on the rate of degradation of organic pollutants
in water. Although irradiation of NOM produces some reactive species, its radical
98
scavenger effects are significant enough to potentially decrease the rate of pollutant
degradation in practical applications (Nienow et al., 2008). To test this hypothesis,
lindane degradation experiments were carried out in the presence of 1 mg/L humic acid.
Similarly, several kinds of synthetic organic pollutants can be found in the water sources
in nature. Two common pollutants namely chloroform (CHCl3) and chlorophenol (2-CP)
were selected as model synthetic pollutants and the effect of these pollutants on gamma
radiation-induced degradation of lindane in aqueous solution was investigated. Figure 3.9
shows the effect of CHCl3, humic acid and 2-CP on gamma radiolytic lindane
degradation in water. The results showed that all these organic substances had small
negative effect on the degradation rate of lindane. The HA is a scavenger of •OH (Nienow
et al., 2008), while its reaction with hydrated electron is not reported. CHCl3 and 2-CP
have high reaction rate constants with eaq− and •OH, however, results showed that lower
concentrations of these pollutants do not significantly affect the lindane removal
efficiency. From these results, it is obvious that the presence of humic acid, 2-CP and
CHCl3 in the low concentration ranges of real-world application do not affect lindane
degradation significantly. The various reactions occurring in the gamma irradiated
lindane solution containing 2-CP and CHCl3 can be the following (Haag and Yao, 1992,
Buxton et al., 1988):
CHCl3 + e‒
aq → Products (k = 3.0 × 1010 M−1 s−1) (3.31)
CHCl3 + •OH → CCl3
• + H2O (k = 5.2 × 107 M−1 s−1) (3.32)
CHCl3 + H• → Products (k = 1.2 × 107 M−1 s−1) (3.33)
2-ClC6H4OH + •OH → Products (k = 1.2 × 1010 M−1 s−1) (3.34)
2-ClC6H4OH + e‒aq → Products (k = 1.3 × 109 M−1 s−1) (3.35)
99
Absorbed dose (Gy)
0 500 1000 1500 2000 2500
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0
H2O2 = 0mM
H2O2 = 5 mM
H2O2 = 10mM
H2O2 = 20mM
Figure 3.8. Effect of concentration of H2O2 on lindane degradation by gamma-ray
irradiation. Experimental conditions: [lindane]0 = 3.43 µM, pH = 6.8, N2-
saturated.
Absorbed dose (Gy)
0 500 1000 1500 2000 2500
C/C
0 (
lin
da
ne
)
0.0
0.2
0.4
0.6
0.8
1.0
CHCl3
Humic acid
2-CP
Blank
Figure 3.9. Effect of humic acid, chloroform and chlorophenol on lindane degradation
by gamma-ray irradiation. Experimental conditions: [lindane]0 = [2-CP] =
[CHCl3] = 3.43 µM, [humic acid] = 1 mg/L, N2-saturated.
100
3.3.8 Pulse radiolysis of lindane–Hydrated electron rate constants (eaq− + lindane)
Pulse radiolysis can be used to determine fast reaction kinetics and spectra of
short lived transients produced during radiolysis of aqueous solutions. The radicals
produced in the electron pulse radiolysis of water can be selectively removed by the
addition of certain scavengers, to allow measurement of the rate constant of a single
radical with a substrate. For selective monitoring of hydrated electron reaction with
lindane, experiments were performed in a N2-saturated 60 M i-PrOH solution that
scavenges •OH radicals and •H atoms to form the relatively inert radical (reactions (3.15)
and (3.16)). The rate of decay of the transient absorbance at 700 nm was used to monitor
the reaction of hydrated electrons with lindane.
Lindane + eaq− → Product (3.36)
The decay curves fit an exponential rate law, indicating first order kinetics
behavior. Plotting these pseudo-first order values against lindane concentration, a second-
order rate constant of k = (1.26 ± 0.04) × 1010 M˗1 s˗1 was obtained. Thus, the rate
constant for hydrated electrons reaction with lindane is of the order of diffusion-
controlled reaction. This rate constant is approximately two order of magnitude higher
than the reported rate constant of hydroxyl radical with lindane i.e. 2.9 ×108M−1 s−1, as
reported by Nienow and co-workers (2008) and 7.5 × 108 M−1 s−1, as reported by Haag
and Yao (1992). This rate constant is in good agreement with the value reported for
reactions of hydrated electron with other chlorinated hydrocarbons; where values 1.4 ×
1010 and 1.3 × 1010 M˗1 s˗1 have been reported for CHCl3 and CCl4, respectively (Schmidt
et al., 1995, Buxton et al., 1988).
101
3.3.9 Competition kinetics–Hydroxyl radical rate constant (•OH + Lindane)
Unlike hydrated electron, hydroxyl radical has small absorption in the accessible
region that is not useful for determination of rate constant. Therefore, a competitive
kinetics method was adopted to determine the absolute (second-order) rate constant of the
hydroxyl radical (•OH) with lindane. The 2-chlorophenol (2-CP) which has well known
second-order rate constant with •OH radical was used as reference compound. The
second-order rate constant of •OH with lindane was determined by using equation (3.38)
(Haag and Yao, 1992);
0
0
ln
2 ln 2 2
t
t
lindane lindanek lindane
k CP CP CP
(3.37)
0
0
ln2
ln 2 2
t
t
lindane lindanek lindane k CP
CP CP
(3.38)
where k(lindane) and k(2-CP) are the second-order rate constants for the reaction of •OH
with lindane and 2-chlorophenol, respectively. [lindane]0 and [2-CP]0 represent the
initial concentrations of lindane and 2-chlorophenol, respectively and [lindane]t and [2-
CP]t represent the concentrations of lindane and 2-CP, respectively, at reaction time “t”.
From the above reaction (3.38), the second-order rate constant of lindane with •OH was
determined to be 6.8 × 108 M−1 s−1, which is consistent with the literature values of 7.5 ×
108 M−1 s−1 (Haag and Yao, 1992) and 2.9 ×108M−1 s−1 (Nienow et al., 2008), where the
•OH radical was generated by photo-Fenton’s or UV/H2O2 reactions, respectively.
Comparing these rate constant data, it appears that radiolytic decay of lindane occurs
mainly by reductive pathway via hydrated electron reaction.
102
3.3.10 Variation of solution pH during irradiation
Figure 3.10 describes pH values of lindane solution before and after gamma
radiation. It is evident that solution pH decreases during gamma irradiation. Higher
absorbed dose resulted in more distinct decrease in pH values. The decrease of solution
pH values is probably due to the formation of organic acids during the degradation
process (Wren and Glowa, 2000). Similarly, the hydronium ion (H3O+) produced in the
irradiation process (equation (1.6)) may also cause the reduction of pH. Figure 3.10
shows that at absorbed dose of 2000 Gy, the pH of the solution was reduced from 6.8 to
4.8.
103
Absorbed dose (Gy)
0 500 1000 1500 2000
pH
4.0
4.5
5.0
5.5
6.0
6.5
7.0
Fig. 3.10. Variation of pH value with the increasing radiation dose in gamma radiolytic
lindane decay. Experimental conditions: [lindane]0 = 3.43 µM, N2-saturated.
104
3.3.11 Identification of by-products and possible reaction pathways
Gas chromatography-mass spectrometry (GC/MS) analysis of the irradiated
lindane solutions showed a number of reductive as well as oxidative intermediates. The
major organic intermediates identified during gamma irradiation included
pentachlorocyclohexene (PeCCH), tetrachlorocyclohexene (TeCCH), 1,4-
cyclohexanedione and various short chain organic acids, such as formic, acetic, succinic
and tartaric acids. Among these by-products, pentachlorocyclohexene (PeCCH) and
tetrachlorocyclohexene (TeCCH) are the widely reported intermediates formed when
lindane is decomposed in various processes, such as photocatalysis, microwave
decomposition and reduction by zero valent iron (Salvador et al., 2002, Wang et al.,
2009; Senthilnathan and Philip., 2010). Due to the presence of high electronegativity
chlorine atoms in lindane, it is easily susceptible to attack by the hydrated electrons
(Taghipour and Evans, 1997). The hydrated electrons of water radiolysis can remove one
or more electrons from lindane in single or multiple steps, resulting in the generation of
different kinds of reaction intermediates. The PeCCH can simply be obtained by
eliminating one HCl molecule (dehydrochlorination reaction) from lindane by the
reaction of hydrated electron. The PeCCH molecule on further dehydrochlorination may
lead to the formation of TeCCH (Li et al., 2011). According to Wang and co-workers
(Wang et al., 2009), lindane may be reduced by the electron, forming a double bond by
eliminating one HCl (dehydrochlorination) to give PeCCH or it may lose two Cl−
(dichloroelimination) to form tetrachlorocyclohexene (TeCCH). Similar intermediates
have been reported during photolysis of lindane in the presence of polyoxometalate
(PW12O403−), where aqueous electron (e−
aq) and hydroxyl radicals (•OH) both exist in the
105
reaction mixture (Antonaraki et al., 2010). Dechlorination reactions may eventually
introduce double bond and unsaturation in lindane molecule and thus oxidation reactions
by •OH radicals are involved. Hydroxyl radicals generally have high rate constant for
reactions with aromatic compounds and unsaturated alkenes (Güsten et al., 1981). •OH
radical has strong electrophilic nature and it may abstract hydrogen atom from
chlorinated hydrocarbons (Spinks and Woods, 1990). Similarly, lindane may also be
decomposed by abstraction of hydrogen atom by the •OH. However, lindane is less prone
to oxidation due to the non-aromatic and fully saturated structure (Dionysiou et al.,
2000). The dehydrochlorination of lindane by the hydrated electron may create
aromaticity in the molecule. The further degradation of aromatic compound leads to ring
cleavage reaction generating a mixture of low-molecular-weight organic acids
(Brinkmann et al., 2003; Fan et al., 2011). The identification of different oxidative
products, such as 1,4-cyclohexanedione and the organic acids suggests that oxidative
pathway is also involved in the gamma radiolytic degradation of lindane. The proposed
degradation pathway of lindane is given in scheme 1.
106
Scheme 1. Proposed lindane degradation pathway by gamma-ray irradiation.
107
3.3.12 Removal efficiency of lindane
Removal efficiency of pollutant can be expressed in several different ways. The
simplest way is the percent (%) removal of pollutant which is obtained by comparing the
concentration of pollutant before and after irradiation as given in equation (3.39):
0
o
C -CPercent removal efficiency = × 100 %
C (3.39)
where C0 is the initial concentration and C is the concentration after radiation treatment.
Another common approach used for determining the process efficiency is the G value.
i.e., the number of solute molecules decomposed per 100 eV of radiation energy
absorbed. The following equation (reaction 3.40) can be used to calculate G value at
various absorbed doses (Lewins et al., 1991; Basfar et al, 2005a):
A
16
ΔR NRadiation chemical yield G, species/100 eV =
D 6.24 × 10 (3.40)
where ΔR is the change in lindane concentration (mol/L) at the given absorbed dose, NA
is Avogadro’s number (6.02 × 1023 molecules/mol), D is radiation dose in Gy and 6.24 ×
1016 is conversion factor from Gy to 100 eV/L.
The G-values obtained under our experimental conditions are presented in Tables
3.7a - 3.7c. G-values provide some useful information about the nature of the radiolytic
reactions. For example, for any radiolytic decay, the G-values less than 0.31 indicate that
there is no radical chain reaction occurring in the system (Getoff and Lutz, 1985). Thus,
lower G-values (˂ 0.31) observed under our experimental conditions (Tables 3.7a - 3.7c)
shows that no radical chain reactions are involved in the present study. From the results
given the Tables 3.7a - 3.7c, it can be seen that the G-values decreased with increase in
108
accumulated absorbed dose. The reduction in G-value with increasing absorbed dose is
due to competition of lindane molecules with the intermediates resulted from lindane for
reactive radicals. The concentration of intermediates is increased with increasing
absorbed dose whereas the concentration of lindane is decreased. Therefore, at
accumulated absorbed dose, the possibility of reactive radicals to react with intermediates
molecules rather than with parent compound increases and hence the G-values decreases.
This trend has been observed in the radiolytic decay of several other compounds (Lin et
al., 1995; Basfar et al., 2005a; Yu et al., 2008).
Still another quantitative way to represent efficiency of solute removal is to
calculate dose constants (or decay constant) ‘k’ that explain the concentration of solute
removed per unit dose. Under our experimental conditions, the concentration of reactive
radicals is in excess to organic solute which can be expressed by pseudo-first order
kinetics. Under pseudo-first order kinetics, the rate of decomposition is directly
proportional to the amount of undecomposed material as mathematically given in
equation 3.11 (in section 3.5). Equation 3.11 is generally used to calculate the dose
constants by determining the slope of the plot of natural logarithm of the solute
concentration (ln[solute]) vs. absorbed dose (Gy). These dose constants can be used to
calculate the dose required for some specific percentage reduction in solute, e.g. for 50
and 90% reduction in the solute concentration as mathematically expressed in reactions
3.41 and 3.42, respectively (Basfar et al, 2005b).
D0.5 = ln (2)/k (3.41)
D0.9 = ln (10)/k (3.42)
109
The values of dose constants ‘k’ obtained under our experimental conditions are provided
in Tables 3.8a - 3.8e. From the data shown in Tables 3.8a - 3.8e, it can be observed that
the dose constants ‘k’ change with the change of the rate of lindane degradation under
different experimental conditions. The dose constant (k) is directly associated with the
rate of solute degradation and inversely related to D0.5 and D0.9. From the results given in
tables 3.8a-3.8e it can be seen that higher the rate of lindane degradation under particular
experimental conditions, higher the values of k and lower the values of D0.5 and D0.9 and
vice versa.
110
Table 3.7a. G-values for lindane removal in the presence of various organic and inorganic substances. Experimental
conditions: [lindane]0 = 3.43 µM, [NO2−] = [NO3
−] = [Cl−] = [HCO3−] = [CO3
2−] = 1 mM, N2-purged for 20 min.
Absorbed
dose (Gy)
G-value
Blank NO2−
NO3−
Cl−
HCO3−
CO32−
CHCl3
(3.43 µM)
Humic acid
(5mg/L)
2-CP
(3.43 µM)
250 0.0699 0.0117 0.0167 0.0619 0.0753 0.0787 0.0502 0.0588 0.0586
500 0.0544 0.0133 0.0167 0.0477 0.0569 0.0586 0.0460 0.0502 0.0502
1000 0.0347 0.0146 0.0159 0.0330 0.0372 0.0376 0.0309 0.0326 0.0343
1500 0.0262 0.0125 0.0139 0.0245 0.0270 0.0273 0.0245 0.0251 0.0260
2000 0.0203 0.0109 0.0121 0.0192 0.0209 0.0209 0.0194 0.0199 0.0201
111
Table 3.7b. G-values for lindane removal in N2O-saturated, aerated and N2-saturated solutions as well as in N2-saturated
solutions containing H2O2, t-BuOH and i-PrOH. [lindane]0 = 3.43 µM.
Absorbed
dose
(Gy)
G-value
N2 N2O Aerated H2O2
(5 mM)
H2O2
(10 mM)
H2O2
(20 mM)
t-BuOH
(60 mM)
i-PrOH
(60 mM)
250 0.0699 0.0101 0.0112 0.0355 0.0167 0.0055 0.0468 0.0385
500 0.0544 0.0083 0.0134 0.251 0.0134 0.0075 0.0418 0.0376
1000 0.0347 0.0083 0.0127 0.0167 0.0104 0.0075 0.0326 0.0284
1500 0.0262 0.0083 0.0111 0.0139 0.0097 0.0069 0.0245 0.0231
2000 0.0203 0.0074 0.0102 0.0125 0.0061 0.0059 0.0192 0.0182
112
Table 3.7c. G-values for lindane removal in gamma rays irradiated N2-saturated aqueous solution; Effect of initial
lindane concentration. pH = 6.8.
Absorbed dose
(Gy)
G-value
[lindane]0 =
0.343 µM
[lindane]0 =
0.694 µM
[lindane]0 =
1.715 µM
[lindane]0 =
3.434 µM
250 0.1004 0.0971 0.0753 0.0669
500 0.0669 0.0653 0.0602 0.0544
1000 0.0397 0.0393 0.0381 0.0347
1500 0.0276 0.0274 0.0270 0.0262
2000 0.0208 0.0208 0.0206 0.0203
113
Table 3.8a. Observed dose constant (k), D0.5 and D0.9 for lindane removal in N2 saturated gamma ray irradiated
aqueous solutions containing 1 mM of different inorganic anions.
Parameters Blank NO2− NO3
− Cl− HCO3− CO3
2−
k (Gy−1) 1.76 × 10−3 3.87× 10−4 4.44 × 10˗4 1.27 × 10−3 2.31 × 10−3 2.55 × 10−3
D0.5 (Gy) 3.95 × 102 1.79 × 103 1.56 × 103 5.48 × 102 3.01 × 102 2.72 × 102
D0.9 (Gy) 1.31 × 103 5.96 × 103 5.18 × 103 1.82 × 103 9.99 × 102 9.03 × 102
114
Table 3.8b. Observed dose constant (k), D0.5 and D0.9 for lindane removal in N2O-saturated, aerated and in N2-saturated
containing CHCl3, humic acid and 2-CP solution.
Parameters
N2 N2O Air CHCl3
(3.43 µM)
Humic acid
(5mg/L)
2-CP
(3.43 µM)
k (Gy−1) 1.76 × 10−3 2.24 × 10−4 3.40 × 10−4 1.33 × 10−3 1.48 × 10−3 1.66 × 10−3
D0.5 (Gy) 3.90 × 102 3.10 × 103 2.04 × 103 5.19 × 102 4.69 × 102 4.17 × 102
D0.9 (Gy) 1.31 × 103 1.03 × 104 6.77 × 103 1.72 × 103 1.56 × 103 1.39 × 103
115
Table 3.8c. Observed dose constant (k), D0.5 and D0.9 for gamma ray lindane removal in aqueous solutions containing
inorganic oxidant (H2O2) and common radical scavengers (t-BuOH and i-PrOH).
Parameters H2O2 t-BuOH
(60 mM)
i-PrOH
(60 mM) (5 mM) (10 mM) (20 mM)
k (Gy−1) 4.23 × 10−4 2.85 × 10−4 1.73 × 10−4 1.29 × 10−3 1.31 × 10−3
D0.5 (Gy) 1.64 × 103 2.43 × 103 4.01 × 103 5.36 × 102 5.29 × 102
D0.9 (Gy) 5.45 × 103 8.07 × 103 1.33 × 104 1.78 × 103 1.76 × 103
116
Table 3.8d. Observed dose constant (k), D0.5 and D0.9 for gamma ray lindane removal at four different initial solute
concentrations (0.343, 0.694, 1.715 and 3.43 µM). Experimental conditions: pH = 6.8.
Parameters Lindane
0.343 µM 0.694 µM 1.715 µM 3.434 µM
k (Gy−1) 2.90 × 10−3 2.64 × 10−3 2.20 × 10−3 1.76 × 10−3
D0.5 (Gy) 2.39 × 102 2.63 × 102 3.15 × 102 3.95 × 102
D0.9 (Gy) 7.94 × 102 8.73 × 102 1.05 × 103 1.31 × 103
117
Table 3.8e. Observed dose constant (k), D0.5 and D0.9 for gamma ray lindane removal at three different pH (4, 6.8 and 8).
Experimental conditions: [lindane]0 = 3.434 µM.
Parameters pH = 4 pH = 8 pH = 6.8
k (Gy−1) 3.53 × 10−4 1.07 × 10−3 1.76 × 10−3
D0.5 (Gy) 1.97 × 103 6.46 × 102 3.95 × 102
D0.9 (Gy) 6.53 × 103 2.15 × 103 1.31 × 103
118
3.4 Degradation of Lindane by Photochemical Oxidation
In this section, degradation and kinetics of peroxymonosulfate (PMS, HSO5−) based
photochemical oxidation of lindane was investigated at lab-scale experiments. The
experiments were carried out under the following conditions:
Degradation of lindane by solely PMS or ferrous iron (Fe2+) and direct UV
photolysis
PMS activated by ferrous iron: Fe2+/PMS system
Fe2+/PMS system assisted by tube-light radiation: Tube-light/Fe2+/PMS system
PMS activated by UV radiation: UV/PMS system
UV/PMS system assisted by Fe2+: UV/Fe2+/PMS system
3.4.1 Degradation of lindane by solely PMS or Fe2+ and direct UV photolysis
Initially, control experiments were conducted to determine the lindane removal by
solely PMS or ferrous iron (Fe2+) or direct UV photolysis and the results are presented in
Fig. 3.11a. The results showed that PMS or Fe2+ alone as well as direct UV photolysis did
not give significant degradation of lindane in 3 hour reaction time.
PMS (HSO5−) is a strong oxidizer with standard oxidation–reduction potential
(E0) of 1.82 V and it is capable of oxidizing many organic compounds under various
activation conditions. However, PMS is a stable reagent and reaction rates with organic
molecules are usually very slow such that no appreciable degradation of lindane was
observed in the present study in three hour when 300 µM of PMS was used.
Ferrous iron (Fe2+) does not show any significant degradation of pollutant when it
is applied to the system, individually. The Figure 3.11a shows that at the initial Fe2+
concentration of 300 µM, only 6% lindane was removed in three hours reaction time. It
119
has been reported that less than 5% pollutant removal can be achieved when sufficient
amount of Fe2+ is present for the degradation of PCBs, propachlor (Liu et al., 2012) and
xanthene dye (Wang and Chu, 2011) in aqueous solution.
The result given in Figure 3.11a shows that lindane is resistant to direct UV
photolysis and the decrease in lindane concentration is very small at reasonably high UV
dose. For exposure time of three hours UV radiation, only 8% lindane was removed from
3.43 μM solution of lindane. It is well known that a molecule containing chromophore or
double bond can easily absorb light energy in the UV range (Dantas et al., 2010).
However, lindane molecule with fully saturated structure cannot absorb UV radiation
directly and hence no significant decomposition can be observed in direct UV photolysis.
This is in agreement with the UV absorption spectrum of lindane shown in Figure 3.11b,
indicating no UV absorption in this region. Previous studies have shown comparable
results for direct photolysis of other chlorinated compounds. Zalazar and co-workers
(2007) found that dichloroacetic acid gave no sign of degradation under direct UV
photolysis. Li and co-workers (2012) also found that no observable decrease in the
concentration of monochloro acetic acid occurred upon direct photolysis. The small
amount of lindane degraded in the direct UV photolysis can be attributed to the
production of some reactive species resulting from photolysis of water molecules
(Sheoran, 2008).
Accordingly, it can be concluded that lindane degradation by direct UV
photolysis, solely PMS or ferrous ion is negligible and thus all these systems cannot be
applied for decontamination of lindane contaminated waters, individually.
120
(a)
Reaction time (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lin
da
ne
)
0.4
0.6
0.8
1.0
PMS
Fe2+
UV photolysis
(b)
Fig. 3.11a. Degradation of lindane by solely PMS, ferrous iron (Fe2+) or direct UV
photolysis. Experimental conditions: [Lindane]0 = 3.43 μM, [PMS]0 = [Fe2+] 0 =
300 μM, (b) UV Absorbence spectra of lindane solution at C0 = 3.43 μM.
121
3.4.2 PMS activated by Fe2+: Fe2+/PMS system
Preliminary results showed that neither Fe2+ nor PMS alone lead to any significant
degradation of lindane at ambient conditions in three hours. Both Fe2+ and PMS, being
fairly stable reagents can react with lindane very slowly when present in solution,
individually. Many transition metals, especially divalent metals (M2+) may act as electron
donors to catalyze the decomposition of PMS through one-electron transfer reaction
analogous to the Fenton initiation reaction. Ferrous ion (Fe2+) has many advantages as an
oxidant activator because it is cheap, less toxic and abundant metal in nature (Nfodzo and
Choi, 2011). The formation of sulfate radical (SO4•−) from PMS (HSO5
−) in this Fenton-
like process (Fe2+/PMS system) has been recently explored (Anipsitakis and Dionysiou,
2003, 2004b). The major reactions involved in the production and consumption of SO4•−
using Fe2+/PMS system is given in reactions 3.43-3.46;
Fe2+ + HSO5− → Fe3+ + SO4
•− + OH− (k = 3.0 × 104 M−1 s−1) (3.43)
Fe2+ + SO4•− → Fe3+ + SO4
2− (k = 3.0 × 108 M−1 s−1) (3.44)
SO4•− + HSO5
− → SO5•− + SO4
2− + H+, (k < 1.0 × 105 M−1 s−1) (3.45)
SO4•− + SO4
•− → S2O82−, (k = 4 × 108 M−1 s−1) (3.46)
Although Fe2+ is an activator of PMS, the reaction is kinetically slow and usually
it takes long time for completion. Large quantities of SO4•− are lost due to its scavenging
reactions with Fe2+, PMS (HSO5−) or other SO4
•− as shown in reactions (3.44), (3.45) and
(3.46), respectively. The ferric iron (Fe3+) produced in reactions (3.43) and (3.44) cannot
activate PMS and thus, additional step is required for regeneration of the Fe2+ catalyst.
Thus reaction (3.43) is a limiting step towards the production of SO4•− in the Fe2+/PMS
(dark) system. As a result, only 11% lindane removal can be achieved in three hour, using
122
300 μM initial concentration of Fe2+ and PMS, each. The extent of lindane degradation
by Fe2+/PMS system, however, increased to 25% when prolong reaction time (20 h) is
given to the reaction (results not shown). The results of lindane removal by Fe2+/PMS
system in three hour reaction time are shown in Figure 3.12a. It was found that the
degradation efficiency of lindane increased by increasing the initial concentration of both
Fe2+ and PMS up to certain extent until the molar ratios of lindane: ferrous iron: oxidant
(LFO) is 1:87:87, respectively. Starting with the initial lindane concentration of 3.43 μM,
300 μM Fe2+ and 300 μM PMS was chosen as optimum doses for removal of lindane in
aqueous solution. The results showed that 1:1 catalyst/oxidant molar ratio is the optimum
value and deviation from the 1:1 molar ratio led to a decrease in the removal efficiency of
the Fe2+/PMS system. The 1:1 catalyst/oxidant molar ratio was found as optimized value
in other studies also in the literature (Gupta and Sutar, 2008; Rastogi et al., 2009). As
indicated in reactions 3.52 and 3.53, both Fe2+ and PMS (HSO5−) can scavenge SO4
•−
when these reagents are present in excess amount. Thus moderate quantity of both Fe2+
and PMS are needed for the optimum removal of lindane in the Fe2+/PMS system.
Fe2+ is recognized as a good activator of H2O2 but it exhibits only limited ability
in the activation of PMS for the decontamination of pollutants. Several researchers found
that cobalt (Co2+) catalyst is an efficient activator of PMS, however, the use of Co2+ has
severe environmental concerns and thus Co2+ cannot be a good alternative in practical
applications (Chan et al., 2009; Do et al., 2009). Therefore, there is a need to explore new
methods that can improve the efficiency of the Fe2+/PMS system, which is comparatively
environmental friendly method for the removal of pollutants. Several attempts were made
for enhancing the efficiency of Fe2+/PMS process and one such attempt is the application
123
of light energy that may enhance the catalytic efficiency of transition metal ions in the
oxidation of pollutants. Two typical energy sources i.e. UV-C light and visible light
(ordinary room tube-light) were employed for activation of Fe2+ catalyst and the results
are discussed in the next section.
3.4.3 Fe2+/PMS system assisted by tube-light radiation: Tube-light/Fe2+/PMS system
Very interesting results were obtained when tube-light assisted Fe2+/PMS system
was employed for the degradation of lindane in water. In the presence of tube light
radiation, 3.43 µM lindane solution containing 300 μM Fe2+ and 300 μM PMS at pH 3.0,
led to 40% overall lindane removal in three hours reaction time. Literature study shows
that iron-mediated (photo-Fenton) process is sensitive to light up to wavelengths ≤ 600
nm (Malato et al., 2002) and hence the efficiency of the Fe2+/PMS system is increased in
the presence of tube-light radiation. The enhanced removal efficiency of the tube-
light/Fe2+/PMS system can be attributed to the regeneration of iron catalyst (Fe2+) (Hislop
and Bolton, 1999) resulted from photochemical effects of the tube-light radiation. The
visible light (including tube-light radiation) consists of a wide range of wave-lengths (λ =
300-500 nm) and a portion of this energy may be used for the reduction of Fe3+ into Fe2+
ions (Pignatello, 1992; Zepp et al., 1992; Chong et al., 2010). The reversion cycle of
Fe2+(aq) → Fe3+(aq) → Fe2+(aq) continuously generates SO4•−, provided that the
concentration of PMS in the system is substantial. Alternatively, the absorption of energy
photons by HSO5− ions may directly result in the generation of SO4
•− (reaction 3.47) or it
may excite HSO5− ion which can be used for the reduction of Fe3+ to Fe2+ ion
(Chevaldonnet et al., 1986).
124
The regeneration of the Fe2+ (aq) from Fe3+ (aq) is the rate-limiting step in the
catalytic iron cycle, if small amount of iron is present in the solution (Chong et al., 2010).
In the present study, varying concentrations of Fe2+ and PMS were employed and the
optimum concentrations of Fe2+ and PMS in the tube-light/Fe2+/PMS system were
selected. The results of lindane removal by tube-light/Fe2+/PMS system are shown in
Figure 3.12a. The results showed that the degradation efficiency of lindane increased by
increasing the initial concentration of both Fe2+ and PMS up to certain extent which
ultimately diminished after some optimum values. In Figure 3.12b, variation of rate
constant ‘k’ with the increasing concentration of Fe2+ and PMS for the Tube-
light/Fe2+/PMS system is shown. At the initial lindane concentration of 3.43 μM, the
optimum molar ratio of lindane: ferrous iron: oxidant (LFO) is found to be 1:87:87,
respectively.
125
(a)
(b) Reaction time (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0
Fe2+
/PMS
Tubelight/Fe2+
/PMS
Concentration of PMS or Fe2+
(mM)
0.0 0.5 1.0 1.5 2.0 2.5
Rate
const
ant,
k (
h-1
)
0.00
0.02
0.04
0.06
0.08
0.10
0.12
0.14
0.16
[Fe2+]
[PMS]
Figure 3.12. (a) Lindane degradation as a function of reaction time in the Dark/Fe2+/PMS
and Tube-light/Fe2+/PMS systems. Experimental conditions: [lindane] 0 = 3.43
μM, [PMS] 0 = 300 μM, [Fe2+]= 300μM and pH = 3.0. (b) The variation of rate
constant ‘k’ (h−1) with the increasing concentration of Fe2+ and PMS for the Tube-
light/Fe2+/PMS system is shown.
126
The results given in Figure 3.12b showed that the molar ratios of Fe2+ and PMS
played a significant role in lindane degradation in the tube-light/Fe2+/PMS system. The
results showed that molar ratio of the catalyst/oxidant is a crucial factor in the tube-
light/Fe2+/PMS system. It was found that the system give maximum efficiency when the
catalyst/oxidant molar ratios is 1:1. Variation from 1:1 molar ratio led to a decrease in the
lindane removal efficiency in the tube-light/Fe2+/PMS system. Our results of the 1/1
catalyst/oxidant molar ratios is consistent with the findings of other researchers (Wang
and Chu, 2011). Rastogi and co-workers (2009) tested the efficiency of the Fe+2/PMS
system for PCBs degradation in aqueous and sediment systems and 1:1 was found to be
the optimum ratio among the oxidant and catalyst.
3.4.4 PMS activated by UV radiation: UV/PMS system
UV radiation is generally considered as an efficient activator of oxidants that are
employed in water treatment for the degradation of pollutants (Hijnen et al., 2006; Li et
al., 2012). In the present study, UV/PMS system was applied for the removal of lindane
and the results are shown in Figure 3.13. The results showed that although direct
photolysis did not result in significant lindane degradation, the addition of PMS resulted
in rapid degradation of lindane.
Highly reactive sulfate free radicals (SO4•−, E˚ = 2.5-3.1 V) can be generated by
activation of PMS (HSO5−) with UV radiation via reaction 3.47 (Anipsitakis and
Dionysiou, 2004b; Shukla et al., 2010). The SO4•− generated can act as strong oxidant for
organic compounds via hydrogen abstraction, addition to unsaturated carbon or by
electron removal process (Neta and Zemel, 1977; Huie et al., 1991).
127
Different initial concentrations of PMS were used for removal of lindane in the
UV/PMS system and the corresponding degradation results are shown in Fig. 3.14a. The
pseudo-first order rate constants ‘k’ obtained at using different initial concentrations of
PMS in the UV/PMS process are shown in Table 3.9 and Figure 3.14b. The results given
in Figure 3.14a showed that for a given concentration of lindane, the rate of lindane
degradation increased with increasing the initial concentration of PMS. Such an increase
in the degradation rate with increasing initial PMS concentration was observed in
UV/PMS oxidation of several other pollutants (Chen et al., 2007; Antoniou et al., 2010a).
The enhanced degradation efficiency of the UV/PMS process with increasing initial PMS
concentration is due to increased number of SO4•− radicals produced when higher
concentration of PMS is used. Apart from reaction with organic pollutants, the SO4•− may
react with PMS (HSO5−) or it may also react with itself to generate unreactive species
(reactions 3.44 and 3.45). However, the scavenging effect of these reactions is
comparatively small at lower PMS concentration while it increases with the increase of
PMS concentration. This is in accordance with the results given in Figure 3.14a, which
shows that the relative increase in the degradation rate with increasing PMS
concentration is high in the beginning, while it gradually slows down at higher PMS
concentrations. Under the optimum conditions, using 300 μM PMS, 97% lindane was
removed in 3 h of photolysis, when the lindane: PMS molar ratio is 1:87. The various
reactions involved in the production and consumption of SO4•− by the UV/PMS system is
given in the following reactions (Anipsitakis and Dionysiou, 2004b);
Generation of SO4•− by UV radiations:
HSO5− + hν → SO4
•− + •OH (3.47)
128
Scavenging reactions of the SO4•−, besides the reactions 3.45 and 3.46 include;
SO4•− + H2O → H+ + SO4
2− + •OH (3.48)
(at all pH values)
SO4•− + −OH → SO4
2− + •OH (k= 1.4-7.3 ×107 M−1s−1) (3.49)
(mostly in alkaline pH)
•OH + HSO5− → SO5
•− + H2O (3.50)
129
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0
Direct UV-Photolysis
UV/PMS
Figure 3.13. Lindane degradation as a function of time of photolysis in the (A) direct UV
photolysis and (B) UV/PMS processes. Experimental conditions: [lindane] 0 =
3.43 μM, [PMS] = 300 μM and pH = 6.0.
Table 3.9. Pseudo-first order rate constants for UV/PMS photochemical degradation of
lindane (3.43 µM) in the presence of various amounts of PMS.
No. [PMS]0 (µM) kap (min−1) R2
1 100 4.78 × 10−3 0.998
2 300 1.32 × 10−2 0.978
3 500 2.53 × 10−2 0.966
4 1000 3.40 × 10−2 0.984
5 2000 4.17 × 10−2 0.988
130
(a)
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0[PMS]=0.1 mM
[PMS]=0.2 mM
[PMS]=0.5 mM
[PMS]=1.0 mM
[PMS]=2.0 mM
(b)
Concentration of PMS (M)
0.0 0.5 1.0 1.5 2.0 2.5
Ra
te c
on
sta
nt,
k (
min
-1)
0.00
0.01
0.02
0.03
0.04
0.05
Figure 3.14. (a) Effect of initial concentration of PMS on the UV/PMS Photochemical
degradation of lindane. Experimental conditions: [lindane] o = 3.43 μM, pH = 6.0.
(b) Variation of rate constant ‘k’ (min−1) with the increasing PMS concentration is
shown.
131
3.4.5 UV/Fe2+/PMS system
As stated earlier, both UV radiation and ferrous iron (Fe2+) can activate PMS
independently to generate highly reactive SO4•−. In addition, UV radiation may also be
used for regeneration of the Fe2+ from Fe3+ ions that consequently activate PMS and thus
further increase the concentration of SO4•− (Zepp et al., 1992; Bossmann et al., 1998).
This system was applied for degradation of lindane as well. The result of UV/Fe2+/PMS
system for the removal of lindane is shown in Figure 3.15. The results showed that the
removal efficiency of the Fe2+/UV/PMS system increased with the increasing
concentration of both PMS and Fe2+ up to certain limit until the lindane/catalyst/oxidant
molar ratio is 1: 87: 15, respectively. However, above this optimum level, only slight
increase in the lindane removal efficiency occurred with further increase in the
concentration of PMS. The variation of the observed degradation rate constants, k with
the increasing concentration of both PMS and Fe2+ is shown in Figure 3.16a and Figure
3.16b. When the concentrations of PMS and Fe2+ exceed their optimum values, the rate
of production of SO4•− radicals and its consumption by the scavenging reactions become
comparable and hence only slight increase in concentration of SO4•− is observed
(Anipsitakis and Dionysiou, 2003; Liang et al, 2004; Fernandez et al., 2004).
Surprisingly, a slight decrease in the lindane removal efficiency can be observed when
the amount of Fe2+ surpasses the optimum concentration limits. At such reaction stage,
the scavenging reactions surmount the production rate of SO4•− and hence a slight decline
in the lindane removal efficiency can be observed. Such a decrease in the degradation
rate of pollutants with the increasing Fe2+ concentration is supported by the results of
other researchers (Tamimi et al., 2008; Pagano et al., 2011). In the present study, the
132
optimum values for the oxidant/catalyst concentrations were attained at 6:1 molar ratio,
which gave 97% lindane removal in 40 min.
It is evident from the results that significantly enhanced degradation results were
achieved when UV radiation and ferrous iron (Fe2+) were simultaneously involved in the
activation of PMS for the removal of lindane. Compared to the individual systems of
Fe2+/PMS and UV/PMS which required 3655 and 91 min, respectively for 90% lindane
removal, the combined UV/Fe2+/PMS system requires only 24 mints for the removal of
same quantity of lindane from aqueous solution. The conversion of Fe2+ into Fe3+ ions
(reaction 3.51) may limit the production of SO4•− in the Fe2+/PMS system. The reversion
of Fe3+ into Fe2+ can sustain the generation of SO4•− radicals, provided that the
concentration of PMS in the system is substantial. In the UV/Fe2+/PMS system, the UV
radiation is used in the regeneration of active Fe2+ catalyst from the Fe3+ as shown in
reaction 3.51 (Hislop and Bolton 1999). Thus the synergistic effect of the UV radiation
and ferrous iron (Fe2+) can be the plausible explanation for the greatly enhanced pollutant
removal efficiency of the UV/Fe2+/PMS process.
Fe(OH)2+ +hν→ •OH + Fe2+ (3.51)
133
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lind
an
e)
0.0
0.2
0.4
0.6
0.8
1.0
Direct UV-Photolysis
UV/Fe2+
/PMS
Figure 3.15. Lindane degradation as a function of time of photolysis in the (A) direct UV
photolysis and (B) Fe2+/UV/PMS processes. Experimental conditions: [lindane] 0
= 3.43 μM, [PMS] = 300 μM, [Fe2+] = 50 μM and pH = 3.0.
134
(a)
Concentration of Fe2+
(mM)
0.0 0.2 0.4 0.6 0.8 1.0 1.2
Ra
te c
on
sta
nt,
k (
min
-1)
0.0
0.5
1.0
1.5
2.0
2.5
3.0
(b)
Concentration of PMS (mM)
0.0 0.2 0.4 0.6 0.8 1.0 1.2
Rate
const
ant,
k (
min
-1)
0.00
0.02
0.04
0.06
0.08
0.10
0.12
0.14
0.16
0.18
Figure 3.16. (a) Variation of rate constant ‘k’ (min−1) with the increasing concentration of
Fe2+ for UV/Fe2+/PMS system at [PMS]0 = 300 μM. (b) Variation of rate constant
‘k’ (min−1) with increasing concentration of PMS for UV/Fe2+/PMS system at
[Fe2+]0 = 50 μM. Experimental conditions: [lindane] 0 = 3.43 μM, pH = 3.0.
135
3.4.6 Kinetics of UV/PMS oxidation
UV/PMS system was selected as a model sulfate radical based advanced
oxidation process (SRB-AOP) for the decomposition of lindane in aqueous solution. For
kinetics studies, the experiments were conducted at various initial concentrations of
lindane and at different pH values.
The mechanisms of oxidation by UV/PMS have been investigated extensively,
and it has been found that the rate of degradation of an organic compound using UV/PMS
process results from the contribution of two pathways: direct photolysis and the reactive
radicals attack (Antoniou et al., 2010b; Yang et al., 2010):
44UV OH C SO C
d Ck C k OH C k SO C
dt
(3.52)
where k•OH-C and kSO4−•
-C are the second-order rate constants for •OH and SO4•− reactions
with lindane (C), respectively. Because •OH and SO4•− radical concentration can be
assumed to be constant over the range of reaction, the products (k•OH-C [•OH]) and (kSO4−•
-
C [SO4•−]) are almost constant and can be considered pseudo-first order rate constants
kˈ•OH-C and kˈSO4−•
-C, respectively (Benitez et al., 2006). Thus, the following equation may
be used to describe the degradation of lindane ‘C’ during UV/PMS process:
4
4
UV OH C SO C
UV OH C SO C
d Ck C k C k C
dt
d Ck k k C
dt
d Ck C
dt
(3.53)
Integrating between ‘0’ to ‘t’ with corresponding concentrations of ‘C0’ and ‘C’ yield;
136
0
lnC
ktC
(3.54)
where ‘k’ represents the pseudo-first order rate constant for the overall degradation of the
compound ‘C’ during the UV/PMS treatment. According to equation (3.54), a plot of
−ln[C]/[C]0 versus reaction time should lead to straight lines, with a slope equal to rate
constant, k. From the previous discussion (also shown in Figure 3.11a), it is clear that
direct UV photolysis does not degrade lindane significantly, so, the kUV can be neglected
in above equation (3.54) and thus ‘k’ represents the combined second-order rate constants
of •OH and SO4•− with lindane i.e. k•OH-C and kSO4
−•-C. The second-order rate constant of
•OH with lindane was determined in the previous section (i.e., 3.3.9) using competition
kinetics, which was equal to 6.8 x 108 M−1 s−1. The second-order rate constant of lindane
with SO4•− was subsequently determined to be 1.3 × 109 M−1 s−1, demonstrating a
comparable reactivity of SO4•− and •OH with lindane. The reference compound used was
meta-toluic acid (m-TA), which has a known second-order rate constant of 2.0 × 109 M−1
s−1 with SO4•− (Neta and Zemel, 1977).
3.4.6.1 Effect of initial concentrations of lindane
The influence of the initial lindane concentration was also studied. Figure 3.17a
illustrates the degradation efficiency of lindane at different initial concentrations. The
observed degradation rate constant ‘k’ values obtained for different initial lindane
concentration is given in Table 3.10 and Figure 3.17b. Variation of observed degradation
rate constant, k with change in initial solute concentration is shown in Figure 3.17c. As
expected for the pseudo-first order reaction, the degradation rate increased but the
observed degradation rate constant ‘k’ decreased with increase of the initial concentration
137
of lindane. Literature studies show that decomposition of many organic pollutants at
lower concentration ranges follow first-order kinetics with respect to pollutant
concentration (Tang and Tassos, 1997; Elkanzi and Bee Kheng, 2000; Gao et al., 2012).
The increase in the degradation rate with increasing solute concentration is due to the
increased number of solute molecules reacting with the reactive radicals (SO4•−) per unit
time. The decrease in the observed dose constant ‘k’ with increasing initial solute
concentration is due to the decreased SO4•−/lindane ratio at the fixed concentration of
PMS. Enhanced formation of intermediates at higher initial lindane concentrations may
absorb part of the UV light, therefore, lowering the observed degradation rate constants at
higher pesticide concentrations (Chelme-Ayala et al., 2010). A similar degradation trend
was observed in the degradation of Acid Orange 7 using SR-AOP (Chen et al., 2007).
138
(a)
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lin
da
ne
)
0.0
0.2
0.4
0.6
0.8
1.0 [lindane]= 6.8 M
[lindane]= 3.4 M
[lindane]= 0.68 M
(b)
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
- ln
(C/C
0)
0
1
2
3
4
5
[lindan] = 0.68 M, R2 = 0.9994
[lindan] = 3.4 M, R2 = 0.9916
[lindan] = 6.8 M, R2 = 0.9652
139
(c)
Concentration of lindane (M)
0 1 2 3 4 5 6 7 8
Ra
te c
onsta
nt,
k (
min
-1)
0.005
0.010
0.015
0.020
0.025
0.030
0.035
0.040
Figure 3.17. Kinetics of UV/PMS photodegradation of lindane at different initial solute
concentrations. (a) Change in lindane concentration with time of UV photolysis,
(b) Plots of –ln(C/C0) Vs. time of UV photolysis, (c) Variation of observed
degradation rate constant, k with change in initial solute concentration.
Experimental conditions: [PMS] 0 = 300 μM, and pH = 6.0.
Table 3.10. Kinetics data of lindane photodegradation with UV/PMS processes at
different initial solute concentration
________________________________________________________________________
C0 (µM) kobs (min−1) t1/2 (min) r (n = 3)
0.68 0.0380 18.2 0.978
3.4 0.0253 27.4 0.995
6.8 0.0099 69.5 0.985
140
3.4.6.2 Effect of solution pH
The pH value of the solution is usually an important factor in the study of
pollutant degradation as pH variation may cause changes in the concentration of reactive
species. The pH of the most frequently studied Fenton and photo-Fenton systems is
limited to around 3, while higher pH can result in conversion of the reactive ferrous iron
(Fe2+) into ferric (Fe3+) precipitate and thus hindering the overall rate of pollutant
decomposition (Ghaly et al., 2001). However, degradation study in a wide pH range can
be performed in those systems where no iron catalyst (Fe2+) is being used. PMS, being
the component of an acidic salt, automatically lowers the pH of the solution to acidic
range and normally small amount of acid is needed in case of Fenton-like processes using
PMS as oxidant. The results of the UV/PMS process conducted for the degradation of
lindane at three different pH values (4.0, 6.0 and 8.0) are presented in Figure 3.18. As can
be seen, the rate of lindane degradation is the highest at neutral pH, while it decreases
both at lower as well as at higher pH. The results further showed the extent of retardation
effect is more prominent at higher pH as compared to lower pH side. The lower lindane
degradation efficiency at alkaline pH values can be attributed to the conversion of the
more reactive SO4•− species into •OH radical which take place at higher pH values
(Huang et al., 2002; Romero et al., 2010; Chu et al., 2011). The results obtained in this
study are in agreement with the literature findings where the rate of degradation of
methyl tert-butyl ether (Huang et al., 2002), diphenylamine, acetic acid (Criquet and
Karpel Vel Leitner, 2011) and textile dye (Madhavan et al., 2006) decreased with
increase of the solution pH in various SR-AOPs. Also, the results obtained are consistent
with other studies where the rate of pollutant degradation decreased with the increase of
141
the solution pH in the Fenton and photo-Fenton like processes (Tamimi et al., 2008). A
slight decrease in degradation efficiency at acidic pH is most likely due to the scavenging
effects of •OH/SO4•− radicals by the H+ ion under such conditions (Spinks and Woods,
1990; Huang et al., 2009). Similarly, the standard reduction potential of hydroxyl radical
(•OH) is strongly reduced at higher pH and this may be another factor leading to a
decreased removal efficiency at higher pH (Buxton et al., 1988). In addition, the
formation of carbon dioxide resulted from the degradation of organic pollutant (lindane)
could lead to the accumulation of bicarbonate and carbonate ions under alkaline
solutions, which might inhibit organic pollutant oxidation (Xu et al., 1989). PMS alone
can also interact with bicarbonate species, most likely inducing the generation of
percarbonate ions (Anipsitakis et al., 2005). The concentration of SO4•− may also be
decreased by reaction with hydroxide ions at higher pH values (reaction 3.57), thus
lowering the rate of lindane degradation (Criquet and Karpel Vel Leitner, 2011).
Previous studies by Huang and Huang (2009) have indicated that PMS based
process exhibit better performances at neutral pH and this behavior can make the PMS
oxidant as the best option for degradation of organic pollutants in real-world applications.
Our result is consistent with the results reported by Zheng and Richardson (1995) and is
coincidentally similar to the findings of Huang and Huang (2009).
3.4.6.3 Effect of humic acid on the UV/PMS system
Humic acids (HAs) are yellow- to black-colored macromolecular substances that
constitute a considerable fraction of natural organic matter (NOM) in surface waters.
NOMs can have an effect on the rate of photodegradation of organic pollutants by virtue
of •OH radical scavenger. It may also absorb light (inner filter effect) and can undergo
142
different photochemical reactions. Although NOMs can produces some reactive species
on irradiation, its inner filter effect and radical scavenger effects are significantly high
and likely to decrease the rate of pollutant degradation in practical applications. To test
this hypothesis, lindane degradation was carried out in the presence of 1 mg/L of humic
acid. Figure 3.19 shows the effects of humic acid on UV/PMS photochemical degradation
of lindane. The results showed that the rate of degradation dramatically decreased in the
presence of HA. At reaction time of 3h, the degradation efficiency of lindane decreased
from 99 to 70%, when 1.0 mg/L humic acid was added to solution. This is because HA
acts as radical scavenger via competing for •OH and SO4•−. Beltran and co-workers
(1998) have demonstrated the scavenging effects of humic acids on the degradation of
nitrobenzene and 2,6-dinitrotoluene. Gogate and Pandit also concluded that high
concentration of humic acid can act as strong scavenger for hydroxyl radicals (2004).
Guan and co-workers (2013) reported that the degradation efficiency of atrazine
decreased from 98% to 23% when 3.2 mg/L of NOM was added to the solution. Chu and
co-workers (2011) demonstrated that presence of NOMs, especially the humic acid, will
quench the radicals in the UV/S2O82−/H2O2 process. Therefore, pre-treatment caution
should be considered to reduce the retardation effect due to the presence of non-target
compounds, such as HA in real applications.
143
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lind
an
e)
0.0
0.2
0.4
0.6
0.8
1.0
pH = 8.0
pH = 4.0
pH = 6.0
Fig. 3.18. Effect of solution pH on UV/PMS photodegradation of lindane. Experimental
conditions: [lindane] 0 = 3.43 μM and [PMS] 0 = 300 μM.
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0 1 mg/L humic acid
Blank
Figure 3.19. Decomposition of lindane as a function of time in the presence of humic
acid. Experimental conditions: [PMS] = 300 μM; [Humic acid] = 1 mg/L and
[lindane]0 = 3.43 μM.
144
3.4.6.4 Effect of inorganic anions on the UV/PMS process
Since real waters usually contain inorganic ions coexisting with organic pollutants,
the effect of inorganic anions on the degradation of lindane was studied at the anions
initial concentrations of 1mM. The inorganic ions investigated include CO32−, HCO3
−,
SO42− and Cl−, which were added as sodium salts of these anions. Under the ion free
condition, 99% lindane was removed at 3 hour reaction time. In the presence of various
ions, the percent removal efficiency of lindane was changed to different levels as shown
in Figure 3.20. The results showed that the rate of degradation was greatly decreased with
the addition of HCO3− and CO3
2− ions. The presence of Cl− and SO42− ions only slightly
decreased the degradation efficiency of the process. The effects of Cl− on the degradation
mechanism can be different under various oxidation conditions. Several researchers
reported that Cl− can have negative effects on pollutant removal efficiency (Ocampo-
Perez et al., 2011). However, Wiszniowski and co-workers (2003) have shown that the
addition of Cl− did not have any influence on the mineralization of organic matters. Wang
and co-workers (2011) recently reported that the rate of Acid Orange 7 is increased in the
presence of Cl− ions. Maurino and co-workers (1997) reported, the presence of HCO3−
has strong negative effect on the efficiency of the H2O2/UV and S2O82˗/UV processes.
The inhibitory effects of these anions on lindane degradation is mainly attributed to the
scavenging of reactive radicals (SO4•−) by these ions, leading to the formation of less
reactive radicals. The reactions of these ions with SO4•− are given below (Spinks and
Woods, 1990, Huie and Clifton, 1990; Padmaja et al., 1993; Wine et al., 1989).
CO32‒ + SO4
•− → CO3•− + SO4
2‒ (k = 4.1 × 106 M−1 s−1) (3.55)
HCO3‒ + SO4
•− → CO3•− + SO4
2‒ + H+ (k = 2.8 × 106 M−1 s−1) (3.56)
145
Cl‒ + SO4•− → Cl• + SO4
2‒ (k = 2.6 × 108 M−1 s−1) (3.57)
SO42− + •OH → SO4
•− + OH− (3.58)
Photochemical removal rate of lindane was modified in the following order: blank
> SO42− > Cl− > CO3
2− > HCO3−. The results showed that photochemical reaction was
rigorously inhibited by CO32− and HCO3
−, while it was lightly affected by the SO42− and
Cl− ions. At any rate, the enhanced negative effects of these ions on the photochemical
decomposition of lindane would be considered in real water samples as these ions are
ranked among the commonest anions.
146
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lin
da
ne
)
0.0
0.2
0.4
0.6
0.8
1.0 No additive
SO4
2-
Cl-
CO3
2-
HCO3
-
Fig. 3.20. Decomposition of lindane as a function of time in the presence of different
inorganic anions. Experimental conditions: [PMS] = 300 μM; [Additive ions] =
1000 μM, [lindane] = 3.43 μM.
147
3.4.7 Mineralization study
It has been reported that some of the intermediate and final by-products generated
during degradation process can be more toxic than the parent organic compounds (Idaka
et al., 1987, Sweeney et al., 1994). Mineralization of pollutants into harmless inorganic
or organic constituents is usually an important parameter in the ultimate removal of toxic
compounds in advanced waste water treatment. Mineralization studies were carried out
by evaluating the removal of total organic carbon (TOC) in the lindane solutions at
different time intervals. Figure 3.21 shows the results of the TOC removal in the lindane
solutions (C0= 17.15 μM) in different photochemical processes using PMS as oxidant. As
can be seen in Figure 3.21, the highest TOC removal efficiency (92%) was achieved in
the UV/Fe2+/PMS system. The main reason is that UV/Fe2+/PMS system provides the
most favorable conditions for the generation of SO4•− and •OH radicals in the system. The
overall production and destruction of SO4•− and •OH radicals by the UV/Fe2+/PMS system
has already been discussed in the previous sections. The SO4•− and •OH radicals produced
in the UV/Fe2+/PMS system are ultimately involved in the oxidation and mineralization
of organic pollutants.
In the present study, varying amount of Fe2+ and PMS were employed and effect
of Fe2+ and PMS concentrations on the TOC removal efficiency of the UV/Fe2+/PMS
system was studied. It was found out that the efficiency of TOC removal is greatly
influenced by the concentration of both Fe2+ and PMS. It is found that the TOC removal
efficiency of the system was increased with the increase of PMS concentration. This
trend has also been reported by other researchers (Pagano et al., 2011). The improved
TOC removal efficiency at the higher PMS concentration is due to the increasing number
148
of SO4−• radicals produced under the condition of higher PMS concentration. Three
different PMS concentration i.e. 100, 300 and 500 µM were applied and the TOC
removal efficiency was determined, as presented in Table 3.11.
To test the effect of Fe2+ concentration, two different concentrations of Fe2+ i.e.
50 and 500 µM were applied for a fixed amount of PMS (500 µM) and the TOC removal
efficiency was determined, as presented in Figure 3.22. As can be seen in Figure 3.22, the
TOC removal efficiency was found to decrease with the increase of Fe2+ concentration. It
is found that 92% and 88% TOC removal is achieved in 180 min, when the Fe2+
concentration is 50 and 500 µM, respectively. Thus using 500 µM PMS and 50 µM Fe2+,
92% TOC removal is achieved in the UV/Fe2+/PMS system when the
pollutant/catalyst/oxidant molar ratio is 1:3:30. The decrease in TOC removal efficiency
with increasing Fe2+ concentration can be attributed to enhanced scavenging of SO4•−
radicals by Fe2+ beyond the optimum concentration limit. It can be concluded from the
mineralization results that moderate concentration of PMS (500 μM) can effectively
remove the TOC in lindane solution in the UV/Fe2+/PMS system by using micromolar
quantities of Fe2+ catalyst.
The complete oxidation of lindane to inorganic constituents, like carbon dioxide
(CO2) and chloride (Cl−) is represented stoichiometrically as:
24SO4•− + C6H6Cl6 + 12 H2O → 24 SO4
2− + 6CO2 + 6Cl− + 30H+ (3.59)
Thus, 24 mol of SO4•− is required for complete oxidation of 1 mol of lindane. For
the conditions of this study, the theoretical need of SO4•− with 0.0172 mM lindane is
0.412 mM, however, 0.500 mM SO4•− was used in actual experiments. About 19 % loss
in the concentration of SO4•− occurred in the course of lindane mineralization in the
149
UV/Fe2+/PMS system. The various intermediates formed from lindane decomposition
may be responsible for loss of SO4•− radicals. A part of SO4
•− radicals may be
decomposed by the undesirable reactions of SO4•− with the PMS (HSO5
−) itself and its
reaction with the Fe2+ ions.
Comparing the TOC removal efficiencies of the various systems given in Figure
3.21, it can be seen that UV assisted PMS processes (UV/PMS and UV/Fe2+/PMS)
always exhibited higher TOC removal efficiency as compared to the Fe2+ activated PMS
processes (Fe2+/PMS and Fe2+/PMS/tube-light). Several reasons can be assigned to this
result. From foregoing discussion and also from the literature reports, it is known that UV
radiation and Fe2+ catalyst both can activate PMS to give SO4•− and •OH radicals.
However, the efficiency of the two sources i.e. UV radiation and Fe2+ catalyst in
activating the PMS is different from each other (Antoniou et al., 2010a). Anipsitakis and
Dionysiou (2004b) studied the efficiency of three common oxidants (PS, PMS and H2O2)
for water decontamination under the influence of transition metals and UV radiation and
it was found that UV radiation can more efficiently decompose PMS as compared to the
transition metal ions. Also, in the case of Fe2+/PMS system, significant amount of SO4•−
is scavenged by the Fe2+ itself, thus lowering the TOC removal efficiency in lindane
solution. The results also show that Fe2+ ions can scavenge the SO4•− more effectively
when SO4•− radicals are generated in slow manner like in the case of Fe2+/PMS and tube-
light/ Fe2+/PMS as compared to the UV/Fe2+/PMS system. From the above discussion it
can be concluded that the UV/Fe2+/PMS system is the most efficient method for rapid
mineralization of lindane (92% TOC reduction) compared to the other SO4•− radical
based systems. The increased TOC removal efficiency in the case of UV/Fe2+/PMS
150
system is obviously due to the efficient activation of PMS by the combined effects of UV
light and Fe2+ catalyst. Similarly, the regeneration of Fe2+ catalyst (equation 3.11) by UV
radiation can also contribute to enhanced mineralization in the UV/Fe2+/PMS system
(Faust and Hoigné , 1990; Zhao et al., 2004). It is found that the TOC removal efficiency
of the UV/Fe2+/PMS system decreased with the passage of time. The observed decrease
in the TOC removal efficiency with the reaction time can be attributed to the formation
and accumulation of stable organic acids, which appear in the degradation progresses of
several advanced oxidation processes. The mineralization studies revealed that although
11 and 40% lindane is degraded in the Fe2+/PMS and tube-light/ Fe2+/PMS systems,
respectively in 180 min, the TOC removal efficiency was less than 10% in each case.
This means that there is time span between degradation and mineralization of lindane.
It can be summarized that 6, 9, 36 and 92% TOC removal is achieved in the
Fe2+/PMS, tube-light/Fe2+/PMS, UV/PMS and UV/Fe2+/PMS systems, respectively in 3
hours, using 500 μM of PMS. Thus the order of TOC removal efficiency for different
systems is: UV/Fe2+/PMS > UV/PMS > tube-light/Fe2+/PMS > Fe2+/PMS.
151
Reaction time (min)
0 20 40 60 80 100 120 140 160 180 200
TO
C/T
OC
0
0.0
0.2
0.4
0.6
0.8
1.0
Fe2+
/PMS
Tube-light/Fe2+
/PMS
UV/PMS
UV/Fe2+
/PMS
Figure 3.21. Removal of TOC as a function of time in different processes: (a) Fe2+/PMS,
(b) Tube-light/Fe2+/PMS, (c) UV/PMS and (d) UV/Fe2+/PMS systems.
Experimental conditions: [lindane]0 = 17.15 μM, [PMS]0 = 500 μM in all cases,
[Fe2+]0 = 500 μM for process (a) and (b) and [Fe2+]0 = 50 μM for process (d), pH
= 3.0 for process (a), (b) and (d), and pH = 6.0 for process (c).
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
TO
C/T
OC
0
0.0
0.2
0.4
0.6
0.8
1.0 [Fe2+
] = 500 M
[Fe2+
] = 50 M
Figure 3.22. Effect of Fe2+ concentration on TOC removal in the UV/Fe2+/PMS system.
Experimental conditions: [lindane]0 = 17.15 μM, [PMS]0 = 500 μM, pH = 3.0.
152
Table 3.11. TOC removal efficiency measured under different initial concentration of
PMS.
Time (min) TOC removal (%)
([PMS]0 = 100 µM) ([PMS]0 = 300 µM) ([PMS]0 = 500 µM)
0 0 0 0
40 4.3 16 19
80 6.8 35 42
120 15 56 88
180 22.7 64 92
153
3.4.8 Oxidant residue analysis of UV/Fe2+/PMS process
The remaining amount of PMS with the corresponding decrease in TOC removal
in the UV/Fe2+/PMS system is shown in Figure 3.23. The reaction was started with
different initial concentrations of PMS (100, 300 and 500 μM) and the TOC removal
efficiencies were determined. It can be seen that the amount of PMS oxidant decreases as
the TOC removal proceeds with the reaction time. More than the stoichiometric amount
of PMS or any other oxidant is generally used in the mineralization of pollutant.
Considerable amount of PMS is generally consumed in the degradation of the
intermediate by-products. From Figure 3.23, it can be inferred that the oxidant
decomposition profiles differ from the TOC removal profiles. The plausible reason is that
the SO4•− and •OH radicals may undergo strong radical-radical recombination besides
their reactions with lindane. The undesired recombination reactions of the SO4•− and •OH
species can be significantly minimized when different components of the system such as,
PMS, Fe2+ and lindane are mixed in appropriate ratio.
The stoichiometry of lindane mineralization by PMS oxidant is given in equation
(3.62). The equation (3.62) shows that a total of 0.412 mM of PMS is required for
complete mineralization of 0.0172 mM of lindane. The results of the PMS residue
analysis revealed that 500 µM of PMS is consumed in 180 min and the TOC removal
efficiency is only 92%. The apparent difference (19%) between the stoichiometric and
the experimental amount of PMS can be attributed to the existence of some stable
intermediates generated during the course of lindane mineralization. Thus excess PMS is
needed for decomposition of these intermediate by-products in addition to the amount
required for the target pollutant. Also, some amount of PMS is lost due to the undesired
154
reaction of the PMS with itself and with the Fe2+ ions, as shown in equations (3.3) and
(3.4).
One of the main aims of the PMS residue analysis was to evaluate if the amount
of the PMS applied to the system is totally consumed during the reaction or it may remain
in the system after the degradation of the pollutant. From the simultaneous study of the
PMS residues and the TOC removal, it is easy to device optimum doses of PMS for
decomposing specific amount of pollutant. The PMS residue analysis also provides useful
information about the rate of decomposition and consumption of PMS oxidant. From the
Figure 3.23 it can be seen that PMS is readily decomposed and consumed in the
UV/Fe2+/PMS system.
155
Time of photolysis (min)
0 100 200 300 400
PM
S/P
MS
0
0.0
0.2
0.4
0.6
0.8
1.0
Time of photolysis (min)
0100200300400
TO
C/T
OC
0
0.0
0.2
0.4
0.6
0.8
1.0[PMS] = 100 M
[PMS] = 300 M
[PMS] = 500 M
Figure 3.23. Residues of PMS with subsequent TOC removal as a function of time in the
UV/Fe2+/PMS process at varied PMS concentrations. Experimental conditions:
[lindane] o = 17.15 μM, [Fe2+] o = 50 μM and pH = 3.0.
156
3.4.9 By-product analysis and reaction mechanism of the UV/PMS system
To There were mainly six reaction by-products identified by GC/MS in this study,
i.e., 1,1,2,3,4,5,6-heptachlorocyclohexane (HeCH), 1,2,3,4,5,6-hexachlorobenzene
(HCB), 1,3,4,5,6-pentachlorocyclohexene (PCCH), 3,4,5,6-tetrachlorocyclohexene
(TeCCH), 1,2,4-trichlorobenzene (TCB) and 2,4,5-trichlorophenol (TCP). The identified
by-products, along their molecular formula, molecular weight and chemical structure, are
shown in Table 3.12. These by-products have been reported previously in various
oxidative studies on lindane, e.g., HeCH, HCB, PCCH, TeCCH and TCP in POMs
photocatalysis (Antonaraki et al., 2010), TCB and HCB in the photo-Fenton reaction
(Nitoi et al., 2013) as well as HeCH, PCCH and TeCCH in TiO2 photocatalysis (Zaleska
et al., 1999). In this study, the exact reacting radical could not be distinguished with
certainty because of the coexistence of both •OH and SO4•− in the reaction solution (Khan
et al., 2014, Antoniou et al., 2010a). Due to the similarities in the reaction mechanism of
these two radicals, it is very likely that the detected by-products can be from either
radical reaction. A potential reaction pathway for the degradation of lindane was
proposed and is shown in Figure 3.24, including (1) dechlorination, (2) chlorination, (3)
dehydrogenation and (4) hydroxylation.
(1) Dechlorination reaction is presumably resulted from homolytic scission of the
C-Cl bond upon UV excitation (Guillard et al., 1996, Legrini et al., 1993, Somasundaram
and Coats, 1991). As a result, chlorine (Cl•) is released from lindane, leaving a carbon
centered radical. A subsequent abstraction of hydrogen from adjoining carbon atom by
•OH and/or SO4•− might lead to the formation of PCCH. A sequential loss of further
157
chlorine resulted in the formation of lesser chlorinated by-products such as TeCCH and
TCB.
(2) Chlorination of lindane can be resulted from its reaction with Cl • or Cl2•−. Cl•
and Cl2•− are strong oxidizing species with E0 of 2.4 and 2.0 V, respectively (Alegre et
al., 2000). These oxidizing species may react with organic compounds via addition to
double bond, hydrogen abstraction or electron-transfer reactions (Gilbert et al., 1988).
Thus an abstraction of hydrogen from lindane via Cl• may lead to the formation of HeCH
(reaction (3.60)). A similar explanation has been provided by Antonaraki et al.
(Antonaraki et al. 2010) employing POMs photocatalysis. In fact, the interaction of Cl−
with SO4•− with the subsequent formation of the chlorinated organic compounds in water
has been commonly reported in literature (Anipsitakis et al., 2006).
(3.60)
(3) Dehydrogenation may occur with the abstraction of two adjoining hydrogen
atoms by •OH and/or SO4•− attack. The formation of a stable HCB by-product allowed the
formation of a double bond to be thermal kinetically possible (Guo et al. 2000). The
formation of HCB from lindane via hydrogen abstraction by •OH is also reported
elsewhere (Antonaraki et al. 2010).
(4) Hydroxylation is a process that introduces a hydroxyl group (─OH) into an
organic compound. The addition of the electrophilic •OH to TCB forms a carbon centered
radical, which by addition of O2 yields a peroxy radical. After releasing HO2•, TCP could
158
be formed (reaction (3.61)). Hydroxylation of chlorobenzene and other chlorinated
aromatic compound through such a pathway has been proposed earlier (Drijvers et al.
1998, Zona et al. 2002).
(3.61)
In SO4•− mediated mechanisms, SO4
•− oxidizes the aromatic ring to a radical
cation, which upon hydrolysis leads to the formation of hydroxycyclohexadienyl radical.
The resulting radical, after reaction with O2 and releasing subsequently HO2•, is
converted into a hydroxylated phenolic by-product (reaction (3.62)) (Neta et al. 1977,
Anipsitakis et al., 2006, Walling and Camaioni, 1975).
Though not identified by our method, ring opening and cleavage by-products are
also expected to be formed. The intermediate by-products HCB, TCB and TCP, for
example, were known to mineralize into CO2, H2O and Cl− with an extended reaction
time by photocatalytic and photochemical transformations (Hiskia et al. 2000, Lin et al.
2011, Wang and Chu, 2013).
159
Figure 3.24. Proposed degradation pathway of lindane by UV/PMS. [Lindane]0 = 17.15
μM, [PMS]0 = 500 μM, pH = 5.8.
160
Table 3.12. Reaction intermediates of lindane along with chemical structure, molecular
formula and molecular weight.
Compound name Molecular formula Molecular weight Chemical structure
1,1,2,3,4,5,6-
Heptachlorocyclohexane
(HeCH)
C6H5Cl7
325
Lindane
(γ-HCH)
C6H6Cl6
291
1,2,3,4,5,6-
Hexachlorobenzene
(HCB)
C6Cl6
285
1,3,4,5,6-
Pentachlorocyclohexene
(PCCH)
C6H5Cl5
254
3,4,5,6-
tetrachlorocyclohexene
(TeCCH)
C6H6Cl4
219
2,4,5-Trichlorophenol
(TCP)
C6H2Cl3OH
197
161
(Table 3.12. continue)
Compound name
Molecular
formula
Molecular weight
Chemical structure
1,2,4-Trichlorobenzene
(TCB)
C6H3Cl3
181
162
3.4.10 Degradation of Trichlorobenzene
Trichlorobenzene (TCB) is one of the most commonly reported intermediate
generated during the degradation of lindane by different techniques (Cristol 1947; Orloff
1954; Li et al., 2011). In the current study, TCB was found as a major intermediate
byproducts identified in the UV/PMS and UV/Fe2+/PMS processes. Some of the
important isomers of trichlorobenzene (TCB) are: 1,2,4-TCB, 1,3,4 and1,3,5-TCB. The
three isomers of TCB can be produced in varying amount in different degradation
processes. In our study, all the three isomers were produced; however, the quantitative
amount of the different isomers was not determined, separately.
TCB are colourless liquids with a pleasant smell. They are only slightly soluble in
water, but easily soluble in organic solvents. They are non-flammable and they can easily
decompose to produce toxic gases when heated. TCBs belong to the group of
compounds, commonly known as the volatile organic compounds (VOCs). The main use
of TCBs is in the chemical industry: in the manufacture of dyestuffs and textiles, and in
synthetic oils. They are also used as lubricants and heat transfer fluids, as wood
preservatives, as cleaning agents for septic tanks and in abrasive formulations. TCBs
were used in tropical regions of the world as an insecticide against termites. In the past,
TCBs were also formed during the manufacturing of lindane as a by-product. TCBs can
also be produced as a by-product during industrial cracking (Hooftman and de Kreuk,
1982) and other combustion processes (Jay and Stieglitz, 1995; Panagiotou et al., 1996).
In this part of the study, the efficiency of various UV/oxidant processes, such as
UV/H2O2, UV/PMS and UV/PS for the removal of aqueous TCB were investigated. With
batch experiments, 3.43 μM aqueous TCB solutions were treated in different
163
UV/peroxides systems and the TCB removal efficiency were determined. The TCB
readily undergoes decomposition in the UV/oxidant systems. It is found that all the above
mentioned UV/oxidants systems can effectively degrade TCB. Using the different
UV/oxidant systems, more than 90% TCB was degraded in less than half hour reaction
time. Thus all the three UV/oxidants systems gave good results and the degradation
efficiency varied in the order; UV/H2O2 > UV/PMS > UV/PS. On UV photolysis, H2O2
generate two •OH radicals, PMS generates one SO4•− and one •OH radical, while PS
generate two SO4•− radicals. Thus H2O2 and PMS based processes involve the generation
of •OH radical, while PS process involve only SO4•− radicals generation. •OH radical has
strong affinity for conjugated systems and this seems to be the main reason which is
responsible for higher TCB removal efficiency by the UV/H2O2 system as compared to
the UV/PMS and UV/PS systems.
Pseudo-first order kinetics was used to describe the TCB degradation by various
UV/oxidants systems. Under first order kinetics the rate of decomposition can be
expressed by equation 3.54: (i.e., −ln[C]/[C0] = kt) where Co: initial concentration of
TCB (µM/L); C: concentration of TCB (µM/L) at time t; t: reaction time (min); k:
pseudo-first order rate constant (min–1).
Based on the plots of −ln[C/C0] versus time (t), a linear relationship was
established and it was used to calculate the degradation rate constant ‘k’ from a linear
least-squares fit of the experimental data. In the current study, different initial
concentrations of the various oxidants were applied and efficiency of the photochemical
degradation of TCB was evaluated based on the pseudo-first order reaction rate constants
‘k’. The result of TCB removal by various UV/oxidant is shown in Figure 3.25a, 3.25b
164
and 3.25c. The results showed that for a given concentration of TCB, the rate of TCB
degradation increased with increasing the initial concentration of the oxidant. The
enhanced degradation efficiency of the UV/oxidants processes with the increase in
oxidant concentration is due to increasing number of reactive radicals ( •OH and/or SO•−).
Under the optimum conditions, using 100 μM of oxidant, 98, 95 and 70% TCB was
removed in the UV/H2O2, UV/PMS and UV/PS processes, respectively in 25 min. The
overall production and consumption of •OH and SO•− radicals that can take place in the
UV/H2O2, UV/PMS and UV/PS systems is discussed in detail in the previous sections.
It can be concluded from the results that the reaction follows pseudo-first order
kinetics in all cases. However, the rate of reaction was found to vary with the nature of
the oxidant. In Figure 3.26, comparison of TCB degradation by various UV/oxidants
systems including UV/H2O2, UV/PMS and UV/PS is shown. The overall order of the
various processes is: UV/H2O2 > UV/PMS > UV/PS.
Some useful information can be collected from the degradation of TCB in the
UV/peroxides processes. As compared to the parent compound i.e. lindane, it is seen that
trichlorobenzene (TCB) undergoes faster degradation in the UV/H2O2 process rather than
UV/PMS or UV/PS process. Also, the overall degradation of TCB by UV/peroxides
processes is faster than that of lindane. This is probably due to the presence of
unsaturated bond inside the TCB molecule, that is chemically more reactive towards
oxidation by •OH radical as compared to non-conjugated compounds, such as lindane.
Under the conditions of UV/oxidants alone, TCB undergoes 100% degradation in
reaction time of 40 minutes. On the other hand, less than 40% lindane degradation was
observed when similar experimental conditions were provided. The observed degradation
165
rate constants values ‘k’ calculated from the plots of −ln(C/C0) vs. reaction time were
found to be 3.04 × 10−1, 2.85 × 10−1 and 1.50 × 10−1 min−1 in the UV/H2O2, UV/PMS and
UV/PS processes, respectively.
166
(a)
Time of photolysis (min)
0 10 20 30 40 50
C/C
0 (
TC
B)
0.0
0.2
0.4
0.6
0.8
1.0[H2O2] = 0.1 (mM)
[H2O2] = 0.3 (mM)
[H2O2] = 0.5 (mM)
Time of photolysis (min)
0 5 10 15 20 25 30
-ln(C
/C0)
0
1
2
3
4
5
6
(b)
Time of photolysis (min)
0 10 20 30 40 50
C/C
0 (
TC
B)
0.0
0.2
0.4
0.6
0.8
1.0[PMS] = 0.1 mM
[PMS] = 0.3 mM
[PMS] = 0.5 mM
Time of photolysis (min)
0 10 20 30 40 50
-ln(C
/C0)
0
1
2
3
4
5
6
7
167
(c)
Time of photolysis (min)
0 10 20 30 40 50
C/C
0 (
TC
B)
0.0
0.2
0.4
0.6
0.8
1.0[PS]=0.1 mM
[PS]=0.3 mM
[PS]=0.5 mM
Time of photolysis (min)
0 10 20 30 40 50
-ln(C
/C0)
0
1
2
3
4
5
Figure 3.25. Trichlorobenzene (TCB) decay as a function of UV photolysis time in the;
(a) UV/ H2O2, (b) UV/PMS, (c) UV/PS system. Experimental conditions: [TCB] 0
= 3.43 μM, [H2O2] 0 = [PMS] 0 = [PS] 0 = 0.1-0.5 mM, pH = 5.8. In the inset,
−ln(C/C0) Vs time of photolysis is plotted for determination of rate constant, k.
Time of photolysis (min)
0 10 20 30 40 50
C/C
0 (
TC
B)
0.0
0.2
0.4
0.6
0.8
1.0UV/PS
UV/PMS
UV/H2O2
Time of photolysis (min)
0 5 10 15 20 25 30
-ln(C
/C0)
0
1
2
3
4
5
Fig. 3.26. Comparison of the decay of TCB by PS/UV, H2O2/UV and PMS/UV
processes. Experimental conditions: [TCB]0 = 3.43 μM, Initial oxidant
concentration = 300 μM, pH = 5.8.
168
3.5 Hydroxyl radical based AOP using UV/H2O2 system for lindane degradation
H2O2 (HOOH) is conventionally well known inorganic peroxide and strong
oxidizer with standard oxidation–reduction potential (E0) of 1.776V (Betterton and
Hoffmann 1990). However, the chemical is very stable which can react with substrates at
moderately slow rate. Several kinds of activation sources such as UV radiation, gamma
rays and/or transition metal ions are commonly used as activator of H2O2 oxidant. The
most common AOPs based on H2O2 include Fenton’s reagent (Burbano et al., 2008;
Elmolla and Chaudhuri, 2009) and UV/H2O2 (Xu et al., 2009; Kalsoom et al., 2012).
Several useful reviews have been published on the application of H2O2 in wastewater
treatment (Neyens and Baeyens, 2003; Gogate and Pandit, 2004).
Highly reactive and non-selective hydroxyl radicals (•OH, E˚ = +1.8 to +2.7V)
can be generated by the activation of H2O2 with UV radiation via equation 3.60 (φ=1.0).
Those processes in which the concentration of target contaminant changes with
time, while the concentration of oxidant remains relatively constant, are generally
described by pseudo-first order kinetics. Under first order kinetics, the rate of degradation
is directly proportional to the sum of the material, undecomposed as mathematically
given in equation 3.54. Equation 3.54 is generally used to calculate the degradation rate
constants, k.
Degradations rate constants ‘k’ of lindane and t1/2 described by use of pseudo-first
order kinetics at using different initial concentration of lindane are presented in Table
3.13. The results revealed that the pseudo-first order reaction rate constants decreased
with the increasing initial concentration of lindane. This is in accordance with the results
observed by Danishvar and co-workers, which indicated that the rate of nitro-phenol
169
degradation increased with the decreasing pollutant concentration in the UV/oxidant
process (Daneshvar et al., 2007).
In the current study, different initial concentrations of H2O2 were applied and
efficiency of the photochemical degradation of lindane was evaluated based on the
pseudo-first order reaction rate constants ‘k’. The result of lindane removal by the
UV/H2O2 system is shown in Figure 3.27a and the effect of initial H2O2 concentration on
the degradation rate constant ‘k’ is shown in Figure 3.27b. Table 3.14 gives the pseudo-
first order rate constants, k for degradation of lindane at different initial concentration of
H2O2. In Figure 3.28, the variation of observed degradation rate constant, k with
increasing concentration of H2O2 is shown. The results showed that for a given
concentration of lindane, the rate of lindane degradation increased with increasing the
initial concentration of H2O2. The results further showed that the increase in degradation
rate with the increasing H2O2 concentration is fast in the beginning, while it slows down
with time until the rise becomes very slight after some optimum concentration of H2O2.
The enhanced degradation efficiency of the UV/H2O2 process with the increase in H2O2
concentration is due to increasing number of •OH produced at higher concentration of
H2O2. However, this factor becomes less obvious at the stages when the recombination
reactions among the •OH and the reaction of •OH with H2O2 molecules surmount the
reaction of •OH with lindane. Such an increase in the degradation rate with the increasing
H2O2 concentration is observed in the UV/H2O2 oxidation of several other pollutants
(Behnajady et al., 2004; Riga et al., 2007). Under the optimum conditions, using 500 μM
H2O2, 49% lindane was removed in 180 min, when the lindane/H2O2 molar ratio is 1:87.
170
The overall production and consumption of •OH taking place in the UV/H2O2
process can be given in the following reactions (Christensen et al., 1982, Buxton et al.,
1988, Chen et al., 2011, Khan et al., 2013);
H2O2 + hv → 2•OH (Φ= 1.0 mol einstein−1) (3.61)
•OH + H2O2 → HO2• + H2O, (k = 2.7 x 109 M−1 s−1) (3.62)
2•OH → H2O2 (3.63)
H2O2 → HO2− + H+ (3.64)
•OH + HO2− → H2O + O2
•−, k= 7.5 x 109 M−1s− (3.65)
O2•− + H2O2 → OH− + •OH (3.66)
•OH + HO2• → H2O + O2, k = 1 x 1010 M−1s−1 (3.67)
H2O → HO− + H+ (3.68)
3.5.1 Comparison of the UV/PMS system with UV/H2O2 process
The two peroxides mentioned above (PMS and H2O2) are similar in structure and
both contain O–O bond. One hydrogen atom in H2O2 (HOOH) is replaced by SO3− to
generate HOOSO3− (PMS). Due to the influence of the SO3
−, O–O bond is lengthened
and the bond energy decreases. The distances of the O–O bonds in HSO5− (HOOSO3
−)
and solid H2O2 are 1.453 and 1.460 Å, respectively (Flanagan et al., 1984). The estimated
bond energy in H2O2 is 213.3 kJ/mol, while it is estimated that PMS is less in bond
energy than H2O2 (Reints et al., 2000, Yang et al., 2010). Due to increased O-O bond
length in PMS, it is activated more effectively by UV radiation than the H2O2 oxidant.
Control experiments were conducted to determine the lindane removal by solely H2O2.
The results showed that the H2O2 oxidant alone did not give any significant degradation
of lindane within 3 hour reaction (data not shown).
171
It can be concluded from the results that the reaction follows pseudo-first order
kinetics in each case. The rate of reaction was found to vary considerably with the change
of the oxidant types such that: UV/PMS > UV/H2O2. Our results are in accordance with
literature reports for similar reactions. Antoniou and co-workers (2010a) reported that
UV/PMS system has greater efficiency than UV/H2O2 system in the removal of
microcystin-LR.
172
Table 3.13. Kinetic data of lindane photodegradation with UV/H2O2 ([H2O2]0 = 300 µM)
processes at different initial concentration of lindane.
________________________________________________________________________
C0 (µM) kobs (min−1) t1/2 (min) R2 value
0.68 4.07 × 10˗3 170 0.996
3.4 2.85 × 10˗3 243 0.984
6.8 1.22 × 10˗3 568 0.957
Table 3.14. Pseudo-first order rate constants for degradation of lindane (3.43 µM) by UV
photolysis in the presence of various amounts of hydrogen peroxide.
No. [H2O2]0 (µM) kap (min−1) R2
1 100 2.08 × 10−3 0.955
2 300 2.85 × 10−3 0.984
3 500 3.71 × 10−3 0.946
4 1000 4.14 × 10−3 0.965
5 2000 4.56 × 10−3 0.966
173
(a)
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
C/C
0 (
lindane)
0.0
0.2
0.4
0.6
0.8
1.0
[H2O2] = 0.1 mM
[H2O2] = 0.3 mM
[H2O2] = 0.5 mM
[H2O2] = 1.0 mM
[H2O2] = 2.0 mM
(b)
Time of photolysis (min)
0 20 40 60 80 100 120 140 160 180 200
-ln
(C/C
0)
0.0
0.2
0.4
0.6
0.8
1.0
[H2O2] = 2.0 mM, R2 = 0.9868
[H2O2] = 1.0 mM, R2 = 0.9829
[H2O2] = 0.5 mM, R2 = 0.9573
[H2O2] = 0.3 mM, R2 = 0.9844
[H2O2] = 0.1 mM, R2 = 0.9672
Figure 3.27. (a) Photochemical decay of lindane under different initial concentrations of
H2O2, (b) plots of –ln(C/C0) Vs time of photolysis for different initial
concentrations of H2O2. Experimental conditions: [lindane] o = 3.43 μM, pH = 6.0.
174
Concentration of H2O
2 (mM)
0.0 0.5 1.0 1.5 2.0 2.5
Rate
consta
nt,
k (
min
-1)
0.0015
0.0020
0.0025
0.0030
0.0035
0.0040
0.0045
0.0050
Figure 3.28. Variation of observed degradation rate constant, k with change in
concentration of H2O2. Experimental conditions: [lindane] 0 = 3.43 μM, and pH = 6.0.
175
3.6 Photocatalytic activity of sulfur doped TiO2 (S-TiO2) and TiO2 under Visible light
Figure 3.29 shows the visible light activity (VLA) of S-TiO2 for the degradation of
lindane in aqueous solution. The results of control experiments, including (i) visible light
only, (ii) ref-TiO2/dark, (iii) S-TiO2/dark, and (iv) ref-TiO2/visible light, revealed that
neither activation of ref-TiO2 (band gap energy, EG = 3.18 eV) (Han et al., 2011), nor
direct photodegradation of lindane with visible light (λ > 420 nm) was effective in this
study. The results; however, showed that significant degradation of lindane occurred in
visible light-assisted S-TiO2 photocatalysis (S-TiO2/vis), leading to 31.0% lindane
removal in 6 hr. The VLA of S-TiO2 is associated with its reduced band gap value (i.e.,
2.94 eV), induced by substitutional doping of S2− in the TiO2 lattice (Han et al., 2011).
Consequently, the absorption edge of S-TiO2 was shifted to lower energy region, thereby
capable of absorbing visible light photon for the promotion of electrons to the conduction
band (Han et al., 2011, Umebayashi et al., 2002). The photogenerated electron (e−)
(reaction 4.75) has high reduction potential, capable of reducing surface adsorbed oxygen
(O2), and yielding superoxide radical anion (O2•−) (reaction (4.79)) (Zhao et al., 2014,
Banerjee et al., 2014). Contrary to UV/TiO2 process, the photogenerated hole (h+)
resulted in visible light-assisted S-TiO2 photocatalysis cannot oxidize H2O or HO−,
because of thermodynamics unsuitability, thus avoiding the formation of •OH (Zhao et
al., 2014, Banerjee et al., 2014). However, the formation of •OH in visible light-assisted
S-TiO2 photocatalysis is reported to have taken place via O2•− pathways (reactions (4.80)-
(4.84)) (Goldstein et al., 2008, Zhao et al., 2014). Thus the photogenerated electrons (e−)
and the associated ROSs like O2•− and •OH are most likely responsible for the visible
light-assisted S-TiO2 photocatalytic degradation of lindane. Though mechanisms of
176
visible light assisted doped-TiO2 photocatalysis are not currently well-established, we
will attempt later, to identify the role of various reactive oxygen species (ROSs)
generated in S-TiO2/vis process, based on the reaction intermediates identified via
GC/MS analysis.
TiO2 + hν → hVB+ + eCB
− (4.75)
hVB+ + eCB
− → Energy (4.76)
hVB+ + H2O → •OH (4.77)
hVB+ + HO− → •OH (4.78)
eCB− + O2 → O2
•− (4.79)
eCB− + O2
•− + 2H+ → H2O2 (4.80)
O2•− + O2
•− + 2H+ → H2O2 + O2 (4.81)
O2−• + H+ → HO2
• (4.82)
2HO2• + 2H+ → 2H2O2 + O2 (4.83)
eCB− + H2O2 + H+ → H2O + •OH (4.84)
Degradation of lindane by the visible light-induced S-TiO2 photocatalysis followed
pseudo first-order kinetics, as shown by following equation (4.85):
obs
0
C-ln t
Ck
(4.85)
where C0 and C are the concentration of lindane at initial and after time t, respectively; t
is the radiation time; and kobs is the observed pseudo first-order rate constant. The visible
light-induced S-TiO2 photocatalysis is effective for degradation of lindane. A further
study was performed to investigate the effect of the critical operation parameters such as
177
solution pH, initial concentration of lindane, and catalyst loading on the visible light-
induced S-TiO2 photocatalysis for lindane degradation.
178
Irradiation time (h)
0 1 2 3 4 5 6
C/C
0 (
lindane)
0.6
0.7
0.8
0.9
1.0
Vis light alone
Ref-TiO2/dark
S-TiO2/dark
Ref-TiO2/vis light
S-TiO2/vis light
Figure 3.29.Photocatalytic degradation of lindane using S-TiO2 photocatalyst under
visible light. Experimental conditions: [lindane]0 = 1.0 µM, [S-TiO2]0 = 0.23 g/L,
pH = 5.8.
179
3.6.1 Factors affecting the efficiency of photocatalytic activity of the S-TiO2
3.6.1.1 Effect of solution pH
The solution pH may affect the surface charge on the photocatalyst and also the
state of ionization of the substrate. Thus the adsorption of the substrate as well as its
photocatalytic decay is expected to vary with solution pH (Bhatkhande et al., 2002,
Apkan and Hameed, 2009, Evgenidou et al., 2005a). To investigate the influence of
solution pH on photocatalytic activity of S-TiO2, three different pH values (i.e., 4.0, 5.8
and 8.0) were chosen for lindane degradation under visible light illumination. The results
are shown in Figure 3.30. The results showed that photocatalytic activity of S-TiO2 films
varies significantly with the solution pH. The highest lindane removal was observed at
pH 5.8, corresponding to 31.0% removal in 6 hr. In contrast, the removal efficiency
decreased in stronger acidic as well as basic conditions, indicating 27.2 and 22.4%
removal at pH 4.0 and 8.0, respectively, after 6 hr of visible light irradiation. The lindane
degradation followed pseudo first-order kinetics model in the studied pH range with kobs
of 4.19 × 10−2, 5.93 × 10−2, and 4.14 × 10−2 h−1 for pH 4.0, 5.8, and 8.0, respectively. The
obtained results are in good agreement with the literature reports, dealing with
photocatalytic degradation of other insecticides such as atrazine and dimethoate (Sacco et
al., 2015, Evgenidou et al., 2005a). Since the electrostatic force of attraction or repulsion
between the photocatalyst’ surface and the pollutant is affected by the solution pH
(Evgenidou et al., 2005a, Evgenidou et al., 2005b), the degradation efficiency of S-TiO2
photocatalysis was found to change with the varying pH. At the lower pH value, the
concentration of O2−• is reduced by the reaction with H+ ions (reaction (4.82)) (Hoffmann
180
at al., 1995), and so the removal efficiency of lindane due to O2−• reaction might be
decreased.
The removal efficiency of lindane was also reduced at pH 8.0. It can be attributed
to the surface charge change of photocatalysts, leading to surface electrostatic repulsion
phenomena. Literature studies show that TiO2 photocatalysis of atrazine also resulted in a
lower removal efficiency at the increasing solution pH, i.e., 7 or 10 (Parra et al., 2004).
Above all, our results clearly indicate that the highest photocatalytic activity was
observed at pH 5.8.
3.6.1.2 Effect of initial concentration of lindane
Figure 3.31 depicts the influence of initial concentrations of lindane on the
observed pseudo first-order rate constant, kobs during the S-TiO2 photocatalysis under
visible light irradiation. The kobs were found to decrease with increasing the initial
concentrations of lindane. Under the experimental conditions in this study, the value of
kobs was 6.50 × 10−2, 5.93 × 10−2 and 5.22 × 10−2 h−1 for 0.5, 1.0 and 2.0 µM of initial
concentration of lindane, respectively. The most plausible reason for decreasing kobs
could be the formation of higher concentration of reaction by-products at higher initial
concentration of lindane. The produced reaction by-products can compete with lindane
molecules for ROS, thus lowering the removal efficiency of lindane (Ghodbane and
Hamdaoui, 2010). Our results are in accordance with the findings of Senthilnathan and
Philip (Senthilnathan and Philip, 2010). The removal efficiency of lindane decreased with
increasing initial concentrations of lindane in the solute concentration range of 0.086-
0.517 µM. Wang et al. (Wang et al., 2011) studied the photocatalytic activity of C-N-S-
181
tridoped TiO2 photocatalyst for the removal of tetracycline and found that the removal
efficiency decreases at an increasing initial concentration of tetracycline.
However, the initial degradation rate of lindane (calculated by the change in
concentration with time at an initial reaction time of 1 hr) was determined at three
different initial concentrations (i.e., 0.5, 1.0 and 2.0 µM) and the results are shown in
Figure 3.31. As seen in Figure 3.31, the initial degradation rate of lindane increased since
the number of lindane molecules colliding with ROS increased at higher concentrations
of lindane (Khan et al., 2013). Under these experimental conditions, the degradation rate
of lindane was 5.25 × 10−2, 9.00 × 10−2 and 1.40 × 10−1 µM h−1 at 0.5, 1.0 and 2.0 µM of
initial concentration of lindane, respectively.
Figure 3.32 shows the effect of PMS on TiO2 photocatalysis of lindane under
visible light irradiation. The results of control experiments showed that only 4.1% lindane
was removed by PMS direct oxidation under visible light in 6 hr, indicating that PMS
cannot be effectively activated by visible light irradiation (Figure 3.32). The ref-
TiO2/PMS/vis process showed a 7.0% lindane removal in 6 hr, demonstrating that
addition of PMS had no significant effect on the efficiency of visible light-assisted ref-
TiO2 photocatalysis of lindane. Interestingly, photocatalytic activity of S-TiO2/vis was
significantly increased in the presence of PMS, leading to 68.2% removal of lindane in 6
hr. The enhanced removal efficiency is most probably resulted from the role of PMS as
an acceptor of electrons, thereby reducing the rate of the electron-hole recombination
(i.e., opposing reaction (4.76)) on the photocatalyst surface (Hoffmann at al., 1995). Also,
PMS is an efficient source of SO4•− and/or •OH radicals in the TiO2-based photocatalytic
processes, according to the reactions (4.86) and (4.87) (Malato at al., 1998).
182
HSO5− + eCB
− → •OH + SO42− (4.86)
HSO5− + eCB
− → OH− + SO4•− (4.87)
SO4•− is a strong oxidant with E0 of 2.5-3.1 V (Neta at al., 1988), and it exhibits
high efficiency on the decomposition of many organic compounds (Anipsitakis and
Dionysiou, 2003). Although more selective, SO4•− reacts with organic compounds also
through some common mechanisms like •OH, i.e., hydrogen abstraction, electron
transfer, or addition to double bonds (Khan et al., 2014). Furthermore, SO4•− can also trap
the photogenerated electrons according to reaction (4.88), thereby reducing the rate of the
electron-hole recombination. Besides, SO4•− can interact with water and generate •OH,
according to reaction (4.89):
SO4•− + eCB
− → SO42− (4.88)
SO4•− + H2O → •OH + SO4
2− + H+ (4.89)
The effect of initial concentrations of PMS on the photocatalytic activity of S-
TiO2/vis process was investigated, and the resulting kobs are shown in the inset of Figure
3.32. As can be seen, the value of kobs for S-TiO2/vis process increased as the initial
concentration of PMS is increased. A plausible expalanation for the increasing kobs could
be the increased concentrations of SO4•− and •OH via reactions (4.86) and (4.87)),
obtained at the increasing concentration of PMS (Khan et al., 2016). As stated earlier, the
electron-hole recombination is also inhibited by PMS. So, an increase in the
concentration of PMS might cause enhance inhibition of electron-hole recombination,
thereby increasing the removal efficiency of lindane, and hence the kobs is increased. The
calculated kobs was found to be 1.35 × 10−1, 1.84 × 10−1, 3.25 × 10−1, and 4.82 × 10−1 h−1,
when the initial concentration of PMS was 0.1, 0.2, 0.5 and 1.0 mM, respectively. An
183
initial PMS concentration of 0.2 mM was used in all subsequent experiments, which
yielded 68.2% lindane removal in 6 hr.
A comparison of TiO2 photocatalysis in terms of percent removal efficiency (%)
of lindane was also performed (Table 3.15). The results showed that the percent removal
efficiency of lindane followed the order: ref-TiO2/vis < ref-TiO2/PMS /vis < S-TiO2/vis <
S-TiO2/PMS /vis, which corresponded to 4.2, 7.3, 31.0 and 68.2% lindane removal,
respectively, in 6 hr. The observed pseudo first-order rate constant (kobs) and the
calculated half-life (t1/2) for the processes studied herein are also given in Table 3.15. The
results showed that presence of PMS had no apparent effect on the efficiency of ref-
TiO2/vis, indicating that neither visible light nor ref-TiO2 is effective in activating PMS,
for lindane degradation. The results given in Table3.15 revealed that the half-life of the
various TiO2 photocatalytic processes (except ref-TiO2/PMS/vis) were several fold
reduced in the presence of 0.2 mM PMS, thus making visible light-assisted S-TiO2
photocatalysis a suitable option for application purposes. This study showed that addition
of PMS is very beneficial to TiO2-based photocatalysis by way of reducing the size of
photocatalytic reactor. Consequently, considerably higher removal efficiency of lindane
can be achieved in a comparatively less reaction time.
184
Irradiation time (h)
0 1 2 3 4 5 6
C/C
0 (
lind
an
e)
0.6
0.7
0.8
0.9
1.0
pH0 = 8.0
pH0 = 4.0
pH0 = 5.8
Figure 3.30. Effect of solution pHs on lindane removal efficiency using S-TiO2
photocatalyst under visible light. [lindane]0 = 1.0 µM, [S-TiO2]0 = 0.23 g/L.
[Lindane]0 (M)
0.5 1.0 1.5 2.0
kobs (
h-1
)
0.052
0.054
0.056
0.058
0.060
0.062
0.064
0.066
Initia
l de
gra
da
tion
rate
(M
.h-1
)0.04
0.06
0.08
0.10
0.12
0.14kobs
Initial degradation rate
Figure 3.31. Variation of kobs and initial degradation rate with different initial
concentration of lindane using S-TiO2 photocatalysis under visible light. The initial
degradation rate corresponds to the first hour of decay. [S-TiO2]0 = 0.23 g/L, pH = 5.8.
185
Irradiation time (h)
0 1 2 3 4 5 6
C/C
0 (
lind
ane
)
0.0
0.2
0.4
0.6
0.8
1.0
PMS/Vis
Ref-TiO2/PMS/Vis
S-TiO2/Vis
S-TiO2/PMS/Vis
[PMS] (mM)
0.0 0.2 0.4 0.6 0.8 1.0
k obs
(h-1
)0.0
0.2
0.4
0.6
Figure 3.32. Effect of 0.2 mM PMS on TiO2 photocatalysis of lindane under visible
light irradiation. [lindane]0 = 1.0 µM, pH = 5.8, [S-TiO2]0 = 0.23 g/L. Inset:
variation of kobs with [PMS]0 in the range of 0.1-1.0 mM.
Table 3.15. Pseudo first-order rate constant (kobs), removal efficiency (%) and half-life
(t1/2) of various visible light-assisted (VLA) AOPs based on S-TiO2 photocatalyst
for lindane degradation, in the presence and absence of 0.2 mM PMS. lindane]0 =
1.0 µM, pH = 5.8, [S-TiO2]0 = 0.23 g/L.
________________________________________________________________________
Type of VLA-AOP kobs (h−1) Removal efficiency (%) t1/2 (h)
Ref-TiO2/vis 6.61 × 10−3 4.2 105.0
Ref-TiO2/PMS/vis 1.19 × 10−2 7.3 58.2
S-TiO2/vis 5.93 × 10−2 31.0 11.7
S-TiO2/PMS/vis 1.87 × 10−1 68.2 3.7
186
3.6.1.3 Effects of inorganic oxides on the degradation of lindane in the simulated solar/S-
TiO2 system
Photocatalytic degradation of lindane using S-TiO2 was also investigated under solar
light irradiation and the results are shown in Figure 3.33. As seen in Figure 3.33, direct
photodegradation of lindane by solar light irradiation was negligible within 6 hr.
However, the photocatalytic efficiency of the TiO2 based photocatalysts was significantly
enhanced under solar irradiation, leading to 36.7 and 63.4% lindane removal using ref-
TiO2 and S-TiO2 films, respectively, for 6 hr. Solar radiation consists of about 5% UV
light radiation, which has energy greater than the band gap energy of ref-TiO2, thereby
capable of promoting electrons from valence band to the conduction band, generating an
electron-hole pair (eCB− + hVB
+) (reaction (4.75)). Subsequently, these electron-hole pairs
can generate various ROSs such as O2•− and •OH, as discussed in the previous sections.
Although activation of ref-TiO2 by UV component of solar radiation resulted in a
reasonable degree of lindane degradation, S-TiO2 photocatalysis yielded a far better result
than the ref-TiO2 film mainly because of the potentially strong capacity of S-TiO2 film
for absorbing visible light photons, besides, the increased BET surface area and porosity
of the S-TiO2 film (Han et al., 2011). This is in accordance with the findings of Fotiou et
al. (2015) and Triantis et al. (2012), who reported that various doped-TiO2 based
photocatalysts showed higher performances than reference TiO2 for the degradation of
pollutants under solar irradiation. The observed pseudo first-order rate constants for solar
light-assisted ref-TiO2 and S-TiO2 photocatalysis were found to be 0.73 × 10−1 and 1.63 ×
10−1 h−1, respectively (Table 3.16).
187
The influence of PMS on solar light-assisted TiO2 photocatalysis of lindane was
investigated (Figure 3.33), which showed a tendency similar to that of PMS effect on
visible light-assisted S-TiO2 photocatalysis of lindan. Around 15.0% of lindane was
decomposed by PMS (0.2 mM) direct oxidation under solar light for 6 hr, indicating that
PMS can be activated by solar light radiation. The photocatalytic activity of solar light-
assisted TiO2 photocatalysis was significantly enhanced in the presence of PMS, with
85.4 and 99.9% lindane removal by ref-TiO2/PMS/solar and S-TiO2/PMS/solar processes,
respectively, in 6 hour. The results shown here for the effect of PMS on solar light-
assisted TiO2 photocatalysis of lindane are consistent with above discussion on the effect
of PMS on visible light-assisted TiO2 photocatalysis of lindane (section 4.2.4), i.e.,
reduced rate of the electron-hole recombination and generation of SO4•− and/or •OH.
Moreover, PMS can be directly activated by UV light (a fraction of solar radiation),
thereby generating SO4•− and •OH radicals, as shown in reaction (4.90) (Anipsitakis and
Dionysiou, 2004b). The value of kobs was found to be 3.10 × 10−1 and 5.83 × 10−1 h−1 by
ref-TiO2/PMS/solar and S-TiO2/PMS/solar processes, respectively (Table 3.16).
HSO5− + hν → SO4
•− + •OH (4.90)
The effect of initial concentrations of PMS on the photocatalytic activity of S-
TiO2/solar process was also investigated, and the resulting kobs are shown in the inset of
Figure 3.33. The results showed that the value of kobs increased with increasing
concentration of PMS, plausibly due to the reasons explained in the previous section, i.e.,
increased SO4•− and •OH production as well as enhanced inhibition of electron-hole
recombination at the increasing concentration of PMS. The calculated kobs was found to
be 3.84 × 10−1, 5.81 × 10−1, 8.01 × 10−1, and 9.97 × 10−1 h−1 for S-TiO2/PMS/solar and
188
that of 2.30 × 10−1, 3.03 × 10−1, 4.55 × 10−1, and 5.71 × 10−1 h−1 for ref-TiO2/PMS/solar
when the initial concentration of PMS was 0.1, 0.2, 0.5 and 1.0 mM, respectively. An
initial PMS concentration of 0.2 mM was used in all subsequent experiments, which
yielded 85.4 and 99.9% lindane removal by ref-TiO2/PMS/solar and S-TiO2/PMS/solar
respectively, in 6 hr.
A comparison of TiO2 photocatalysis in terms of percent removal efficiency (%)
of lindane is illustrated in Table 3.16. The results of the present study showed that the
removal efficiency of lindane followed the order: ref-TiO2/solar < S-TiO2/solar < ref-
TiO2/PMS/solar < S-TiO2/PMS/solar, which corresponded to 36.7, 63.4, 85.4 and 99.9%
lindane removal, respectively in 6 hr. The observed pseudo first-order rate constant (kobs)
and the calculated half-life (t1/2) for the processes studied herein are also given in Table
3.16. The results showed that solar light-assisted ref-TiO2 photocatalysis demonstrated
high removal efficiency for lindane, which further increased in the presence of PMS,
indicating that both ref-TiO2 and PMS were activated by solar light irradiation. The
results also revealed that the half-life of the solar light-assisted TiO2 photocatalytic
processes were even reduced in the presence of 0.2 mM PMS, thus making it more
suitable for application purposes, by considerably reducing the size of the photocatalytic
reactors.
189
Irradiation time (h)
0 1 2 3 4 5 6
C/C
0 (
lind
an
e)
0.0
0.2
0.4
0.6
0.8
1.0
PMS/solar
Ref-TiO2/PMS/solar
S-TiO2/PMS/solar
[PMS] (mM)0.0 0.2 0.4 0.6 0.8 1.0 1.2
ko
bs (
h-1
)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4 S-TiO2/PMS/solar
Ref-TiO2/PMS/solar
Figure 3.33. Solar light-assisted TiO2 and S-TiO2 photocatalysis of lindane in the
presence and absence of 0.2 mM PMS . [lindane]0 = 1.0 µM, pH = 5.8, [S-TiO2]0
= [TiO2]0 = 0.23 g/L. Inset: variation of kobs with [PMS]0 in the range of 0.1-1.0
mM.
Table 3.16. Pseudo first-order rate constant (kobs), removal efficiency (%) and half-life
(t1/2) of various solar light-assisted (SLA) AOPs based on S-TiO2 photocatalyst
for lindane degradation, in the presence and absence of 0.2 mM PMS. lindane]0 =
1.0 µM, pH = 5.8, [S-TiO2]0 = 0.23 g/L.
________________________________________________________________________
Type of SLA-AOP kobs (h−1) Removal efficiency (%) t1/2 (h)
Ref-TiO2/solar 7.31 × 10−2 36.7 9.5
S-TiO2/solar 1.63 × 10−1 63.4 4.3
Ref-TiO2/PMS/solar 3.10 × 10−1 85.4 2.2
S-TiO2/PMS/solar 5.83 × 10−1 99.9 1.2
190
4 CONCLUSIONS AND FUTURE PERSPECTIVES
4.3 Conclusions
The effective degradation of lindane by gamma irradiation was plausibly due to its
high second-order rate constant with eaq−, i.e., 1.26 ± 0.04 × 1010 M˗1 s˗1, as determined
by pulse radiolysis techniques. The concomitant background constituents, such as NOM
and various inorganic ions showed significant influences on the process efficiency,
indicating a need for pretreatment, aiming at the removal of those constituents for the
purpose of practical applications. The pH of the solution also had a considerable effect on
the process efficiency. The highest removal efficiency was obtained at neutral pH (6.8).
Despite high inhibition from the concomitant background constituents, effective lindane
removal could still be achieved, though at relatively higher radiation doses. The nearly
complete dechlorination of lindane may indicate the gamma radiation based AO/RPs to
be a promising technology for water detoxification, considering the common relationship
of chlorinated organic compounds with toxicity.
The SO4•− radical reacted with lindane with a second-order rate constant of 1.3 ×
109 M−1 s−1, as determined by competition kinetics, making the degradation of lindane to
be plausible by UV/PMS based AOPs. The observed pseudo-first order rate constant
(kobs) was affected by the initial concentrations of PMS and lindane as well as the solution
pH. The presence of humic acid, CO32− or HCO3
− caused a strong inhibiting effect while
the presence of SO42− or Cl− exerted a negligible effect on the efficiency of UV/PMS
process. Various degradation by-products, as identified by GC/MS, revealed
dechlorination, chlorination, dehydrogenation and hydroxylation to be potential
transformation pathways. Ring opening and cleavage could also be achieved indirectly as
191
demonstrated by the significant decrease in TOC. This study shows UV/PMS based AOP
is an effective method for the removal of lindane from aqueous solution.
The Fe2+/HSO5− based processes was evaluated for the degradation and
mineralization of lindane from aqueous solution and found to be enhanced in the
presence of fluorescence light and also by UV light irradiation. The lindane degradation
followed pseudo-first order kinetics in the tested AOPs. The efficiency of the
UV/Fe2+/HSO5− system increased with increasing concentrations of either Fe2+ or HSO5
−
but decreased with increasing pH. The observed pseudo-first order rate constant of
lindane by UV/Fe2+/HSO5− was found to decrease with increasing concentration of
contaminant while the initial degradation rate increased with higher lindane
concentrations. The Fe2+/HSO5− and fluorescence light/Fe2+/HSO5
− processes showed
limited ability in the mineralization of lindane, while UV/Fe2+/HSO5− system presented a
much better TOC removal efficiency. HSO5− was readily decomposed, especially in the
systems containing both Fe2+ and UV radiation, consistent with lindane degradation and
mineralization efficiencies. Overall, considering degradation kinetics, UV/Fe2+/HSO5−
system is the most efficient for the degradation and mineralization of lindane in this
study.
Nanocrystalline S-TiO2 films, synthesized by a sol–gel method, exhibited
significant photocatalytic efficiency for the degradation of lindane under visible light
irradiation. The efficiency of S-TiO2 photocatalysis was affected by the concentration of
the contaminant and the solution pH. The highest photocatalytic degradation of lindane
was observed at near neutral pH (5.8). TiO2 photocatalysis significantly improved under
solar irradiation. The addition of 0.2 mM HSO5− showed a remarkable enhancing effect
192
on TiO2 photocatalysis of lindane, causing many fold reduction in the half-lives of the
reaction. Therefore, by adding HSO5−, sizes of photocatalytic reactors can be
considerably reduced in practical applications. Based on the results, key operating
parameters were optimized. The results indicated that solar or visible light-active TiO2-
based AOPs are very effective for the detoxification of water contaminated with
chlorinated pesticides, such as lindane.
The surface water samples collected from district Swabi, Khyber Pakhtoonkhwa,
Pakistan, showed high concentration of lindane. The high lindane residues in the field
water samples of district Swabi shows that despite ban, lindane is still being used in
Pakistan for agriculture purposes. Canal water was comparatively highly contaminated
with lindane, probably due to the discharges from the agriculture fields.
4.4 Future Perspectives
The relatively positive influence of fluorescence light (e.g., tube-light) on the studied
Fenton-like process may suggest a further research need and a potential application of
Fe2+/HSO5− in field, by using other long wavelength light sources such as UV-vis
(including solar light) and UVA. The photocatalytic activity of the synthesized S-TiO2
may be evaluated for the removal of other pollutants, particularly the chlorinated organic
compounds. The effect of natural sun light on photocatalytic activity of S-TiO2 for
lindane degradation may also be investigated. The efficiency of the studied AOPs may
also be checked for the treatment of the field waters contaminated with lindane, which
probably will provide useful scientific informations on the extension of AOPs in the real-
world applications. The relatively high lindane concentrations detected in the analyzed
water samples may suggest proper education should be given to the farmers about the
193
hazardous effects of this toxic pesticide to avoid its use in future. The residence of the
region should be warned about the use of surface water for drinking purposes. More
detailed study is needed to explore such other toxic pesticides prevailing in this region.
The current study can be extended to other regions of Pakistan in order to get a clear
baseline data for the entire country. Based on the results obtained, it is recommended that
the government of Pakistan should take strong action against the use of these persistent
toxic pesticides for agriculture purposes.
194
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