art salamanca fuel 90 2011
TRANSCRIPT
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Air quality assessment in a highly industrialized area of Mexico: Concentrationsand sources of volatile organic compounds
Elizabeth Vega, Gabriela Snchez-Reyna , Virginia Mora-Perdomo, Gustavo Sosa Iglesias, Jos Luis Arriaga,Teresa Limn-Snchez, Sergio Escalona-Segura, Eugenio Gonzalez-Avalos
Instituto Mexicano del Petrleo, Eje Central Lzaro Cardenas 152, Col. San Bartolo Atepehuacan, Distrito Federal C.P. 07730, Mexico
a r t i c l e i n f o
Article history:
Received 24 August 2010
Received in revised form 29 March 2011
Accepted 31 March 2011
Available online 24 April 2011
Keywords:
VOCs
Air quality
Industrial areas
Halocarbons
Mexico
a b s t r a c t
Parallel to the economical benefits brought by the oil industry in Mexico, there have been some negative
environmental effects due to emission of pollutants to the atmosphere. Salamanca, a city located inside
one of the most important industrial corridors of the country, has been frequently affected by elevated
concentrations of sulfur dioxide and particle matter. However, little is known about volatile organic com-
pounds (VOCs), which in this study are analyzed along with criteria pollutants and meteorological
parameters during FebruaryMarch 2003 at urban, suburban and rural sites. Although sulfur dioxide
average levels were $0.017 ppm, a high concentration event ($0.600 ppm), attributable to emissions
from the oil refinery and the thermoelectric power plant, was observed at the urban site at night time.
The VOCs concentration varied from 170 50 ppbC (rural) to 699 212 (urban) and were constituted
by 40% alkanes, 13% aromatics, 11% olefins and 11% of halogenated. The most abundant species were pro-
pane (167 40 ppbC), n-butane (91 23 ppbC), toluene (51 10 ppbC) and i-pentane (44 7 ppbC), that
are related to combustion processes. Freon-114, methyl bromide and 1,2-dichloroethane which are likely
emitted by application of pesticides, soil fumigation and fabrication of chemicals, showed high concen-
trations (48 10, 50 10 and 32 6 ppbC respectively) in the rural sites, highlighting the importance
of control measurements implementation for these species, as they represent a potential hazard for pub-
lic health. Moreover, these halocarbons showed similar ratios regardless the monitoring site, suggesting
same source. Modeling results indicated that meteorological conditions generally transport air masses to
the northeast rural areas where the highest concentrations of ozone were calculated.
2011 Elsevier Ltd. All rights reserved.
1. Introduction
Over the last century, the oil industry has emerged as the pri-
mary energy source [1]. Currently, the life style of human societies
depends on energy (electricity generation, natural gas, crude oil
and its refined products, coal, etc.); without it, societies as we
know them would collapse. Even though the oil industry has made
important contributions to the global economy, usually this has
been accompanied with negative environmental impacts from avariety of activities such as oil drilling, refinery, oil spillage, gas
and flaring. Moreover, deterioration of the environment may not
be circumscribed to the local scale, it can reach regional and global
extent due to the emission of precursors of secondary pollutants
and chemical species that contribute enhancing global warming
and stratospheric ozone depletion [24]. Public health may also
be affected if emissions contain toxic or carcinogenic species [5].
In recent years concern over public health and environmental pro-
tection has become a critical issue, this means that a growing
amount of investment and effort is dedicated to reconcile the envi-
ronment and development of countries.
The economy of Mexico strongly depends on oil industry; in
2005 the primary distillation capacity (1540 MBD) ranked the
country on the top 15 worldwide and 4 in Latin America. The crude
is processed in 6 oil refineries which mainly produce gasoline, die-
sel, jet fuel, coal, asphalt, and lubricants. The third most important
refinery is the Ing. Antonio M. Amor, which processes 197 MBD [6].
The refinery and a variety of industries constitute one of the mostimportant industrial corridors of Mexico, known as the Bajo Indus-
trial Corridor (BIC) located in the State of Guanajuato, in the central
area of the country (Fig. 1). The BIC has nearly 465 industries, from
medium to large size, including Chemical, Power Generation, Food
Processing, Textile and Metal-mechanic [7].
The Salamanca city, with 250,000 inhabitants, is located at
203400900N latitude and 1011105100W longitude, at 1720 m above
mean sea level [8]. The Salamanca municipality encompasses a
total area of 774 km2. The agriculture is now the second most
important economical activity, with a designated area of about
80% of the municipality. The impact of agriculture on the environ-
ment is important, especially for the use of fertilizers, pesticides,
0016-2361/$ - see front matter 2011 Elsevier Ltd. All rights reserved.doi:10.1016/j.fuel.2011.03.050
Corresponding author. Tel.: +52 55 91757558.
E-mail address: [email protected] (G. Snchez-Reyna).
Fuel 90 (2011) 35093520
Contents lists available at ScienceDirect
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j o u r n a l h o m e p a g e : w w w . e l s e v i e r . c o m / l o c a t e / f u e l
http://dx.doi.org/10.1016/j.fuel.2011.03.050mailto:[email protected]://dx.doi.org/10.1016/j.fuel.2011.03.050http://www.sciencedirect.com/science/journal/00162361http://www.elsevier.com/locate/fuelhttp://www.elsevier.com/locate/fuelhttp://www.sciencedirect.com/science/journal/00162361http://dx.doi.org/10.1016/j.fuel.2011.03.050mailto:[email protected]://dx.doi.org/10.1016/j.fuel.2011.03.050 -
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deforestation in the uplands and post-harvesting burning. The big-
gest impact to the atmosphere is represented by the post-harvest-ing burning, due to the emission of large amounts of ozone
precursors and particulate matter [8].
According to the 2000 BIC Emissions Inventory, the emissions of
particles (PM10), sulfur dioxide (SO2), carbon monoxide (CO), nitro-
gen oxides (NOX) and hydrocarbons (HC) were 71,443, 112,480,
1,650,772, 142,183 and 260,296 tons per year, respectively. It is
estimated that PM10 are released to the atmosphere mainly by
commercial and service activities, SO2 and NOX by electricity gen-
eration, and CO and hydrocarbons by vehicle exhaust. Salamanca
contributes with 18% of PM10, 92% of SO2, 8% of CO and HC and
14% of NOX of the total BIC emissions. Thus, Salamanca is by far
the major generator of SO2 emissions in the region; while other cit-
ies release ozone precursors [8].
Parallel to the economical development of the BIC, there havebeen some adverse environmental impacts which have brought
the attention of government agencies, civil and private associa-
tions. As a result, since 2000 a Monitoring Network in Salamanca
routinely measures CO, SO2, NO2, O3, and PM10. According to local
environmental authorities, the SO2 air quality standard, AQS,
(0.13 ppm in a 24 h average, no more than once per year) was ex-
ceeded 13%, 24% and 22% of days in 2000, 2001 and 2002 respec-
tively in downtown Salamanca, mainly during winter. The
exceedences of other gaseous pollutants is less frequent, for in-
stance, NO2 and CO have been practically below their AQS
(0.21 ppm, 1 h average, and 11 ppm in 8 h average respectively)
[8].
Although total mass of criteria pollutants is routinely measured,
little is known in this highly industrialized region about the gas-eous and particle contaminants that are not included in the local
monitoring network, such as the volatile organic compounds
(VOCs). The negative effects of VOCs on the environment and pub-
lic health are well documented. From the environmental point of
view, some VOCs (i.e. olefins and aromatics which are mainly
anthropogenic) are reactive species that break out the natural
equilibrium of generationdestruction of tropospheric ozone, thus
the concentrations of this compound and other photochemically-
produced pollutants are frequently high in the urban environment.Besides, the reactive organic gases can partition into the aerosol
phase generating secondary organic aerosols. Other important
group of VOCs is constituted by the halogenated species, which
are originated almost exclusively from anthropogenic emissions
due to its usage as an industrial solvent and degreaser. Some of
these compounds have been the focus of intensive research, such
as the chlorofluorocarbons due to their participation in the strato-
spheric ozone depletion. In addition, many of the halogenated spe-
cies represent a potential hazard to human health due to the toxic
and/or carcinogenic effect [915].
The public opinion on air quality deterioration in Salamanca,
encouraged PEMEX (National Oil Company) to support an exten-
sive 2-week monitoring field study with the aim of augmenting
the knowledge of sources, transport and fate of air pollutants in
the region, therefore effective control measurements of atmo-
spheric pollution can be designed. The main findings of such cam-
paign are presented in this work, particularly the chemical
characterization, distribution and origin of VOCs, as well as the
meteorological parameters that influence the dilution and trans-
port of pollutants. The later was also estimated by applying a 3 D
air quality model.
2. Field campaign
As an outcome of a collaborative effort, the Instituto Mexicano
del Petroleo (IMP), the Instituto de Ecologa de Guanajuato, the
Instituto de Investigaciones Cientficas at the Universidad de Guan-
ajuato, the Centro de Ciencias de la Atmsfera at the UniversidadNacional Autnoma de Mxico, the Patronato de Salamanca, and
the Ing. Antonio M. Amor Oil Refinery, with the PEMEX sponsor-
ship, carried out a field monitoring campaign, from February 21
to March 9 2003. The main objectives were to chemically charac-
terize the air pollution in the urban area of Salamanca in both
the particle and gas phases, and to assess the potential impact of
pollutants in the regional scale. The interested reader can consult
Vega et al. [16] for the particulate matter results found in this
region.
The first week of measurements was focused on the character-
ization of urban air quality; while the second week was designed to
evaluate the regional impact of urban emissions. The monitoring
sites of the urban domain (10 10 km) and of the regional domain
(80 80 km) are shown in Fig. 2A and B. Table 1 shows site loca-tion, description, sampling period and measurements performed.
Three automated samplers (VOCCS-ANDERSEN and AVOCS-
ANDERSEN models) with a Viton diaphragm pump were used to
collect VOCs (defined in this work as hydrocarbons from C2 to
C12) in canisters over 12 h period (06001800 and 18000600 local
time) in the urban sites and 24 h period in the rural/boundary sites.
A total of 80 canisters were analyzed in the Laboratory by cryo-
genic pre-concentration/high-resolution GC technique, similar to
the TO-14A protocol [17].
Water Sep-Pak DNPH-Silica cartridges were used to trap car-
bonyl species. Twelve samples were taken during the first week
of the campaign at Cruz Roja (CR) urban site from 0600 to 0900
and from 1200 to 1500. The derivatives were eluted and analyzed
by HPLC with UV photodiode array detector according to the TO-11A protocol [18]. Criteria pollutants were measured using a
GuanajuatoState
Salamanca
County
(B)
Zacatecas
Sn. Luis Potos
Jalisco
Michoacn
Quertaro
Len
Irapuato
Salamanca
Celaya
(A)
Fig. 1. Geographical location of: (A) Salamanca County and (B) The Bajo Industrial
Corridor.
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mobile Lab equipped with conventional analyzers (Monitor Labs).
Methods used to determine these pollutants were NOM-034
SEMARNAT 1993 using dispersive spectroscopy for CO (detectionlimits from 0 to 50 ppm); NOM-037 SEMARNAT 1993 using
quimioluminescence for NOx (detection limits from 0 to
0.50 ppm); USEPA EQOA 0193 091 using UV photometry
for O3 (detection limits from 0 to 1.0 ppm) and USEPA EQSA
0193 092 using pulse fluorescence for SO2 with detection limits
from 0 to 1.0 ppm.
Along the field campaign, the surface meteorological parame-
ters temperature (T), relative humidity (RH), wind speed (WS),
wind direction (WD), atmospheric pressure (P) and solar radiation
(SR) were also measured at three sites in the urban area and at four
in the boundary sites. The vertical thermodynamic profile variables
(P, T, RH and horizontal wind vector) were measured using a Dig-
icora II radiosonde system from Vaisala (Model SPS-220). Three
radiosondes were launched every day at 0800, 1200 and 1800 atSI, JR and VS sites. The information was used to determine the mix-
ing height based on potential temperature and specific humidity
profiles, and also as input for the mesoscale meteorological model
RAMS [19] and the 3D air quality model [20].
3. Results
3.1. Criteria pollutants
The average and standard deviation for 1 h average concentra-
tion of criteria pollutants (CO, NO2, SO2 and O3) and nitrogen oxi-
des (NOX) at urban (CR and DIF), suburban (CG and US) and rural
(MI, JR and VS) sites are shown in Table 2. As expected, the atmo-
spheric concentrations of CO, NO2 and NOX were considerably
higher at the urban sites compared with the suburban and rural
ones. The suburban sites are surrounded by crop fields and un-
paved small roads with little traffic of heavy-duty vehicles which
may influence the measurements, however it is expected to beminimal.
(A)
(B)
-101.30 -101.25 -101.20 -101.15 -101.10 -101.05 -101.00
20.50
20.55
20.60
20.65
20.70
CG
VAUS
CA
CR
NADIF
RT
-101.6 -101.5 -101.4 -101.3 -101.2 -101.1 -101.0 -100.9 -100.8 -100.7
20.1
20.2
20.3
20.4
20.5
20.6
20.7
20.8
20.9
21.0
VS
PN
JR
SI
MI
SALSAL
Fig. 2. Monitoring sites location: (A) Urban Area: Cruz Roja (CR) and DIF; suburban: Crdenas (CA), Cerro Gordo (CG), Universidad la Salle (US), and Valtierrilla (VA); the
Refinery (R) and the Power Plant (T). (B) Regional Area: Silao (SI), Mirandas (MI), Juventino Rosas (JR), Pueblo Nuevo (PN) and Valle de Santiago (VS), SAL is the Salamanca City.
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Regarding ozone, it is noticeable that average levels in the urban
sites were 0.022 ppm with maximum of 0.094 ppm, while the rural
sites reached 0.031 ppm in average and 0.114 ppm maximum. The
diurnal variations of this oxidant at CR (urban), suburban (CG) and
rural (MI and VS) have been plotted in Fig. 3. For all sites, maxi-
mum levels took place from 1200 to 1500, being about 40% higher
in the rural site (MI) than the urban and suburban ones. The mon-
itoring site of VS located within a natural protected area, 25 km
south of the city at an altitude 300 m above the level of Salamanca,
registered ozone average concentration of 0.038 ppm and maxi-
mum of 0.052 which could be considered as background concen-
trations. These results are within the range of ozone levels
reported at rural areas of Canada [21]. In addition, it is known that
areas of high altitude (the study region is 1720 m above sea level)
could be influenced by inputs from free troposphere [2123]. As it
is discussed later, the peak of mixing height was observed every-
day at 1800 reaching 3500 m above ground level, making possible
this phenomenon, although more measurements would be neces-
sary to reach a conclusion.
The highest ozone concentrations were measured at rural MI
which is located 6.5 km north of the city. To investigate the influ-
ence of surface wind direction and speed on the spatial distributionof ozone, an analysis was performed dividing the data-set into four
subsets according to surface wind direction: north (31545), east
(45135), south (135225) and west (225315). As expected,
the results reflected the influence of site location regarding main
pollution sources. The concentrations of ozone at MI were higher
when the wind blew from the west and south, i.e., the site was
downwind major pollution sources. These wind directions were
observed $64% of the time, mostly from 1200 to 1900, which sug-
gest that ozone levels at MI were strongly influenced by trans-
ported ozone. Moreover, the correlation analysis indicated that
levels observed at MI and CR are associated during this meteoro-
logical condition (R2 = 0.72). The same analysis was performed
using data of the opposite wind direction (north), showing an even
stronger relationship (R2
= 0.91) between the urban and ruralozone levels. It has to be added that north winds generally blew
Table 1
Location and type of monitoring sites during the monitoring field Campaign in Salamanca, Mexico. FebruaryMarch 2003.
Site name, code and
coordinates
Site type Site description Measurement
period
Measurements
Cruz Roja (CR) 20.58N,
101.20W
Urban Located in the main street of Salamanca with high vehicular (light and duty) traffic all
day; 2 km west of the Refinery and the Power Plant
February 21
March 9 2003
Criteria pollutantsa,
VOCs, carbonyl
species
DIF 20.56N, 101.20W Urban Located in a residential area with high vehicular traffic, mainly of gasoline-powered
vehicles
February 21
March 9 2003
Criteria pollutantsa
Crdenas (CA) 20.63N,
101.22W
Suburban The site is in a crop field near an unpaved road with little vehicular traffic February 22
28 2003
Criteria pollutantsa
Cerro Gordo (CG)
20.59N, 101.13W
Suburban 7 km southwest of the Refinery and Power Plant, 200 m of a highway used mainly by
heavy-duty vehicles. The site is surrounded by crop fields
February 21
28 2003
Criteria pollutantsa,
VOCs
Valtierrilla (VA)
20.56N, 101.13W
Suburban Located in a populated community with moderate transit of gasoline and diesel
vehicles
February 22
28 2003
Criteria pollutantsa
Universidad La Salle
(US) 20.55N,
101.23W
Suburban Located inside the University, southwest Salamanca; site is surrounded by vegetation;
400 m away from a four-lane road with light and duty-vehicles traffic
February 21
28 2003
Criteria pollutantsa,
VOCs
Silao (SI) 20.59N,
101.42W
Rural/
boundary
The site was used for meteorological measurements, located northwest Salamanca March 29
2003
Radiosondes
Valle de Santiago (VS)
20.35N, 101.20W
Rural/
boundary
Located inside a natural protected area known as Siete Luminarias. The site is 300 m
above the Salamanca level, 1.5 km away from a road with little vehicular traffic
March 29
2003
Criteria pollutantsa,
radiosondes
Pueblo Nuevo (PN)
20.55N, 101.35W
Rural/
boundary
The site is surrounded by crop fields near one unpaved road with little light-duty
vehicular traffic
March 29
2003
Criteria pollutantsa,
radiosondes
Juventino Rosas (JR)
20.64
N, 101.00
W
Rural/
boundary
22 km northeast Salamanca, in a commercial area with buildings 46 m height with
moderated vehicular traffic
March 19
2003
Criteria pollutantsa,
VOCs, radiosondesMirandas (MI)
20.56N, 101.14W
Rural/
boundary
This monitoring site is located 6.5 km north Salamanca, in an wide-open area
surrounded by crop fields
March 19
2003
Criteria pollutantsa,
VOCs
a Criteria Pollutants were measured each minute and include O3, CO, NO2, SO2 and PM10.
Table 2
Basic statistics of concentrations of pollutants (ppm) in urban (CR and DIF), suburban (CG and US) and rural (JR, VS and MI) sites of Salamanca.
Species Urban Suburban Rural
Average Maximum Minimum SD n Average Maximum Minimum SD n Average Maximum Minimum SD n
O3 0.022 0.094 0.001 0.018 699 0.021 0.072 0.001 0.017 353 0.034 0.114 0.001 0.020 525
CO 2.200 19.500 0.960 1.150 699 0.158 1.890 0.001 0.240 347 0.038 0.570 0.001 0.067 525
SO2 0.017 0.310 0.001 0.043 699 0.016 0.269 0.001 0.034 294 0.011 0.318 0.001 0.026 525
NO2 0.022 0.064 0.002 0.013 699 0.014 0.047 0.002 0.008 353 0.010 0.046 0.001 0.008 525
NOX 0.055 0.425 0.002 0.045 699 0.029 0.127 0.001 0.028 344 0.014 0.092 0.001 0.013 525
0.00
0.01
0.02
0.03
0.04
0.05
0.06
0.07
0.08
0 3 6 9 12 15 18 21
CR MI CG VS
O3(ppm)
Fig. 3. Hourly average ozone concentration (ppm) at urban (CR), suburban (CG) andrural (MI and VS) sites of Salamanca during February 21March 8, 2003.
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from 0000 to 0700 and 2100 to 2300, thus measurements indicate
background concentrations. The same analysis was performed for
urban CR and rural VS; the data-set was filtered so only measure-
ments taken when the rural site was located downwind Salaman-
ca. A correlation coefficient of 0.55 was obtained between these
sites (the site is 25 km south), while similar coefficient was ob-
tained for the analysis using only winds from the south
(R2
= 0.57). In summary, the results suggest that transport of airmasses from downtown Salamanca and the elevation of the study
area play an important role in the high ozone concentrations ob-
served in the rural sites.
To evaluate the effect of wind direction on the concentration of
the other pollutants, the average and standard deviation of concen-
trations of criteria pollutants and nitrogen oxides were calculated
for each of the wind sectors above described. At CR, carbon monox-
ide and nitrogen dioxide registered higher levels when the wind
blew from the south or east, which is explained by the location
of this site in the northwest of Salamanca. On the other hand,
ozone levels at CR were statistically lower when the wind blew
from the north and higher when the wind blew from east. The con-
centrations of SO2 showed higher values associated with east-
winds (where the refinery is located) and lower for any other wind
direction. At suburban CG, carbon monoxide and nitrogen dioxide
were higher when the wind blew from the east or south, as it was
envisaged. The concentrations of pollutants were higher when the
wind came from the south at the rural site, which is explained by
the sites location (Table 3). Moreover, the observed results agree
with simulation results of transport of air masses, which are dis-
cussed in Section 3.4.
As mentioned before, the largest sources of SO2 in the study re-
gion are the Refinery and the Power Plant facilities, both located in-
side the Salamanca city. Even though emissions are released to the
atmosphere by elevated stacks (3060 m above the ground), the
natural atmospheric processes such as turbulence, thermal inver-
sions and high pressure systems, may increase the concentration
and residence time of pollutants. Fig. 4 exemplifies the typical daily
variation of SO2 concentration. From 0000 to 0600, due to stableatmospheric conditions, the highest concentrations were observed
at CR, located 2 km west of major emission sources (the other two
sites, MI, and JR, are 6.5 km north and 22 km northeast, respec-
tively). From 0600 to 0900 the wind blew from the east, therefore
CR site received directly the SO2 emissions. Around 0900, the sur-
face wind direction blew from SSW, remaining under these condi-
tions the rest of the day, as a result, concentrations at CR showed a
decrement while at MI an increment was registered. It was found
that short-term variability periods (e.g. at CR at 09000930 and
at MI at 12001220 in Fig. 4) were associated to wind speed lower
than 1.0 ms1. According to RAMS modeling results, surface winds
before 0900 were driven by cold air draining from the near moun-
tains towards lowest topographic levels in the basin, accumulating
air pollutants over the city. After 0900 and due to synoptic wind
forcing, the wind blew from SW in the whole area, sweeping pollu-
tants out of the city. The estimated results were validated againstmeteorological measurements finding good correspondence be-
tween observed and predicted values.
During the monitoring campaign, high SO2 concentrations
(>0.60 ppm, 1 min sampling-time) were registered once at CR at
0200; such high concentrations were associated with persistent
east wind direction (8295) and wind speed of 2.6 ms1, which
was higher than the average registered at this time of the night
(1.3 ms1). Moreover, concentrations above the average of toluene,
m,p-xylenes, benzene, Freon-114 and methyl chloroform were also
registered during this event, suggesting emissions from industrial
activities.
The night-time high SO2 concentration events were frequently
observed in 19992002 and were associated with venting activities
of the Refinery and/or Power Plant [8]. However since 2003 the airquality program began to operate in the region, tackling SO2 and
particle matter problems mostly [24]. The control measurements
include the usage of fuels with low sulfur content in the power
plant and an increment in the natural gas consumption thus is pos-
sible that the first positive results were observed during the field
campaign.
3.2. Volatile organic compounds
3.2.1. Concentrations
Approximately 200 chemical species of VOCs were identified
and quantified by GC analysis. A classification was made according
Table 3
Wind directional analysis for concentrations of criteria pollutants (ppm) during FebruaryMarch 2003 in Salamanca, Mexico.
Site Species Wind direction
North (31545) East (45135) South (135225) West (225315)
CR O3 0.016 0.021 0.022 0.021 0.018 0.017 0.021 0.019
CO 1.946 0.927 2.219 1.104 2.937 1.604 2.201 1.094
NO2 0.032 0.010 0.037 0.010 0.034 0.012 0.028 0.010
SO2 0.020 0.046 0.122 0.139 0.012 0.034 0.008 0.020
CG O3 0.024 0.021 0.012 0.012 0.021 0.018 0.020 0.019
CO 0.161 0.229 0.383 0.518 0.264 0.404 0.158 0.275
NO2 0.016 0.008 0.020 0.010 0.016 0.009 0.014 0.008
SO2 0.031 0.046 0.010 0.019 0.030 0.058 0.030 0.049
MI O3 0.016 0.009 0.015 0.010 0.029 0.025 0.044 0.021
CO 0.074 0.151 0.068 0.121 0.129 0.149 0.093 0.136
NO2 0.011 0.005 0.012 0.006 0.017 0.008 0.009 0.007
SO2 0.004 0.007 0.004 0.010 0.032 0.063 0.014 0.047
March 2, 2003
SO
2(ppm)
0.00
0.05
0.10
0.15
0.20
0.25
0.30
0.35
0.40
00:00 03:00 06:00 09:00 12:00 15:00 18:00 21:00 24:00
E S-W
NNE S-SW
N SW N
erraticMI
JR
CR
Fig. 4. Time series for SO2 concentrations at CR, MI and JR during March 2, 2003.
Upper horizontal lines indicate the observed wind direction.
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to the functional group, indicating that alkanes were the most
abundant group ($40% of the total mass), followed by aromatics
($13%), olefins ($11%) and halogenated compounds ($11%). The
total mass concentration for samples taken from 0600 to 1800
(diurnal samples) varied from 699 212 ppbC at the urban site
(CR) to 170 50 ppbC at the suburban site (US), which is located
southwest of the city. The concentrations of VOCs taken from
1800 to 0600 (nocturnal samples) were higher than those mea-sured in the morning, reaching 956 120 ppbC at CR and
554 95 ppbC at US. Moreover, diurnal samples showed different
composition compared to nocturnal samples: the proportion of al-
kanes was higher during the night at CR, while halogenated and
the unidentified groups showed higher percentages at night in
the suburban sites (Fig. 5A and B). The higher levels of VOCs during
the night period were mainly driven by the increase of emissions of
propane, n-butane, i-butane, Freon-114 and toluene. Velasco et al.
[25] reported that VOCs levels for the Mexico City Metropolitan
Area during 2003 fluctuated from 2473 in the industrial area to
83 ppbC in the rural site for morning samples and from 1467 to
81 ppbC for afternoon samples. A simple comparison between val-
ues of VOCs measured in Mexico City and Salamanca, even though
of the difference in sampling-time, indicated that concentrations
observed in Salamanca were similar with some sites of Mexico
City. Regarding the distribution of VOCs by type, it was observed
the same order of abundance (i.e. alkanes > aromatics > olefins),
although the proportion of olefins in Salamanca was twice the con-
centration reported for Mexico City.
The highest concentrations of individual VOCs measured in the
atmosphere of Salamanca during the sampling campaign are de-
scribed in Table 4. At the urban and suburban sites, propane was
the most abundant species, followed by n-butane, toluene and i-
pentane. The first two species are attributable to the wide usage
of LPG for cooking and heating; on the other hand, toluene and i-
pentane may be emitted by both mobile and industrial sources.
Propane and n-butane are reported as the most abundant species
in the atmosphere of Mexico City [25], showing concentrations
similar to those observed in this study.
The halogenated species such as Freon-114, methyl bromide,
1,2-dichloroethane, 1,2-dichloropropane and vinyl chloride
showed levels noticeably high at the suburban/rural sites, espe-
cially during the night time. The concentrations of these speciesare markedly higher than those observed in an industrial area of
China, where Freon-114 and methyl bromide are $16 and $18
pptv [26,27]. Therefore, the results found in this study highlight
the importance of carrying out continuous monitoring of VOCs,
so control measurements can be taken to reduce population
exposure.
Formaldehyde, acetaldehyde and acetone average concentra-
tions were 3.75 1.94, 2.45 1.45 and 7.71 6.38 ppb, respec-
tively. Formaldehyde may have a significant influence on the
local photochemistry, more than any other carbonyl species [28].
However, concentrations of formaldehyde were low in comparison
to those measured in the southwest and downtown Mexico City
(13.3 and 23.9 ppb respectively) [29,30].
3.2.2. Sources of VOCs
According to abundance and spatial distribution of VOCs species
in Salamanca, the following categories can be identified as the ma-
jor contributors:
(1) Vehicular Emissions (gasoline and diesel-powered vehicles).
The emissions of vehicles powered by gasoline and diesel are
highly loaded with ethene, acetylene, propene, MTBE, n/i-
pentane, 2,2-dimethylbutane, 2-methylpentane, benzene,
toluene, and xylenes [31]. These species were observed in
all monitoring sites in concentrations high enough to rank
them among the first 15 (see Table 4). MTBE average levels
were 4.79 3.34 ppbC at the urban site (not shown in Table
4), representing about 1.0% of the total VOCs. By comparison,a percentage lower than 2% is reported for samples collected
in Mexico City [25].
(2) LPG handling and leakage. This source is characterized by
emissions rich in propane, i-butane, and n-butane [32]. Pro-
pane was the major species at all sites (except rural MI).
(3) Refining processes. Emissions from refining processes are
composed by a large variety of species, which depend on
the process itself. It is reported in the literature that ethane,
propane, n/i-pentane, toluene and formaldehyde are emitted
by refining oil processes and by fugitive emissions [33,34].
(4) Other sources: The high levels of halogen species such as
methyl bromide, methyl chloride, 1,2-dichloropropane and
dichloroethane reveal the presence of sources related with
agriculture activities (e.g. application of pesticides and soilfumigants) and with industrial solvent and degrease pro-
cesses [35].
As mentioned previously, burning of agriculture debris has been
a frequent activity in the region that generates large amounts of
particles and gases, mainly CO and organics. The presence of aceto-
nitrile in ambient air indicates this source [36,37]. We have used
styrene as surrogate species for acetonitrile, since the former has
also been considered marker for biomass burning in the rural envi-
ronments [25]. Average concentrations of styrene at the urban site
were 2.0 0.88 ppbC, while concentrations of 2.55 2.27 and
1.10 0.80 ppbC were found at the rural sites MI and JR, respec-
tively. Together, concentrations of styrene and characteristics of
MI site (surrounded by crop fields), suggest that this site is influ-enced by biomass burning emissions. However, no clear relation-
39 38 3641
46
20
816
10
9
19
12
1614
13
4
9
7 1011
1
1
2 43
9
27
21 16 13
7 5 3 5 6
0
20
40
60
80
100
CR CG MI JR US
alkanes olefins aromatics halogenated
oxigenated unidentified HC2
%
(A)
5044
28
14
5
12
17
9
5
4
17
28
1
1 1
921 24
5 4 1
0
20
40
60
80
100
CR US
alkanes olefins aromatics halogenated
oxigenated unidentified HC2
%
(B)
Fig. 5. Distribution of abundance of VOCs in Salamanca. (A) Diurnal samples (06001800); (B) nocturnal samples (18000600).
3514 E. Vega et al./ Fuel 90 (2011) 35093520
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ship was found between styrene and other species indicative of
biomass burning.
A series of scatter plots were constructed to examine the contri-
bution of urban and industrial emissions in the region of study.
Toluene and propene are emitted by both sources; while MTBE is
a distinctive vehicular emission tracer. Fig. 6A shows the scatter
plots for MTBE and toluene and Fig. 6B for MTBE and propene. Both
figures show a subset of data where the two species correlate lin-
early indicating the mobile source, while the second non-corre-
lated subset indicates an industrial origin. The sites mostly
influenced by mobile sources were US, MI, JR and CR, while CG
and in some days CR showed influence by industrial emissions.
This result agrees with the assumption that pollutants are mainly
transported from the city towards northeast, and that CR and CG
were the sites with the higher Refinery and Power Plant emissions
impact.
Propane and n-butane are known fingerprint species of leakages
and unburned LPG [32]. Fig. 6C shows the high correlation between
these species, which is an indication that LPG emissions were hom-
ogenously emitted in the whole area. Mobile sources also contrib-
ute to the levels of propane as corroborated by its correlation with
i-butane, shown in Fig. 6D, particularly with data from US, MI and
JR sites.
As envisaged, the halocarbons species showed no relationship
with compounds which are vehicular or LPG tracers. However,
some halocarbons such as vinyl chlorine and 1,2-dicholorpropane
Table 4
Concentration (ppbC) and standard deviation for the most abundant VOCs in Salamanca during FebruaryMarch 2003.
CR CG US MI JR
06:0018:00 h 18:0006:00 h 06:0018:00 h 18:0006:00 h 06:0018:00 h 18:0006:00 h 00:0023:00 h 00:0023:00 h
1 Propane 81.1 34.2 167.0 40.3 31.6 9.1 55.5 20.6 16.0 10.4 18.2 8.6 18.7 7.6 42.3 13.4
2 i-Pentane 33.9 15.4 43.6 6.7 9.3 3.3 31.8 4.4 16.0 4.6 18.0 8.0 26.9 28.7 14.0 7.7
3 n-Butane 46.2 19.7 90.8 22.9 17.9 4.4 26.7 4.9 9.2 6.0 9.0 4.2 11.4 4.4 20.5 5.3
4 Toluene 37.7 16.5 51.2 10.5 11.6 2.8 13.2 1.5 4.9 2.2 4.8 3.0 6.9 2.9 12.5 5.3
5 m/p-Xylene 28.4 13.0 37.6 15.5 7.9 2.2 8.4 2.6 5.0 1.4 8.3 8.7 22.4 36.1 10.8 7.7
6 Ethane 23.6 18.3 20.1 7.1 5.6 2.4 5.3 3.1 2.9 1.7 1.6 1.1 2.1 0.8 2.9 1.6
7 Acethylene 9.1 2.3 14.9 8.4 6.7 1.6 6.5 2.5 4.0 2.9 2.9 2.2 4.7 2.8 10.7 11.1
8 Benzene 17.2 7.1 19.5 2.5 7.3 1.7 7.2 2.8 4.2 2.5 3.3 1.9 5.0 3.4 6.9 3.2
9 i-Butane 18.0 8.4 33.1 7.5 7.7 2.3 11.1 2.9 3.4 2.2 3.3 1.9 4.2 2.5 10.8 3.2
10 Ethylene 19.4 13.6 17.2 6.5 7.3 3.6 7.6 5.3 3.3 2.4 2.4 1.8 2.5 1.1 3.4 2.2
11 Propene 16.8 10.0 18.3 8.6 3.7 1.0 4.4 0.9 1.3 0.6 1.4 0.7 0.6 0.7 2.3 3.4
12 n-Pentane 13.6 5.6 15.6 3.8 6.6 1.8 5.8 1.7 1.6 1.0 2.3 1.3 6.1 1.4 4.7 1.9
13 2,3-Dimethylbutane 10.3 6.0 14.6 2.3 3.3 1.7 4.3 0.9 2.1 0.9 2.9 1.0 2.3 1.1 5.5 3.3
14 o-Xylene 10.9 6.0 12.8 2.3 3.1 0.9 3.1 0.8 1.4 0.6 2.5 2.4 7.3 10.6 3.9 2.4
15 3-Methylbutene 41.4 71.8 18.4 4.3 0.6 0.5 0.5 0.3 5.6 3.4 0.4 0.4 5.3 9.8 1.9 0.7
16 Freon-114 8.6 2.7 14 8 a a 7.1 4.1 14.0 4.2 8.9 3.3 18.0 1.7
17 Methyl bromide a a 9.0 3.0 28.4 3.9 a 48.3 9.7 a a
18 1,2-Dichloroethane 2.8 3.0 2 0.4 9.6 3.1 31.8 4.3 0.2 0.1 49.9 10.1 1.6 1.2 2.3 1.7
19 Methyl chlorine 3.6 3.0 5.1 6.4 1.3 0.3 1.6 0.7 1.0 0.3 1.2 0.5 1.0 0.2 1.1 0.2
20 1,2-Dichloropropane 1.1 0.6 1.2 0.2 7.0 2.3 21.4 3.7 a 32.3 5.9 a a
21 Vinyl chlorine 6.1 2.7 7.7 1.5 1.9 1.8 1.7 0.6 0.3 0.2 0.4 0.3 0.6 0.2 1.5 0.8
a Not available.
0
10
20
30
0 10 20 30 40 50 60 70 80 90
MTBE(ppbC)
Toluene (ppbC)
Mobile
Industry
(A)R2=0.98
0
10
20
30
0 10 20 30 40
MTBE(ppbC)
Propene (ppbC)
Mobile
Industry
(B)
R2=0.95
0
50
100
150
200
250
300
0 30 60 90 120 150
Propane(ppbC)
n-butane (ppbC)
CR
CG
LS
MI
JR
(C)R2=0.97
0
50
100
150
200
250
300
0 10 20 30 40 50 60
Propane(ppbC)
i-butane (ppbC)
CR
CG
LS
MI
JR
(D)R2=0.92
Fig. 6. Scatter plots of selected species and its relationship with main local sources in Salamanca, Mexico. FebruaryMarch, 2003.
E. Vega et al. / Fuel 90 (2011) 35093520 3515
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showed moderate association with toluene, which is probably due
to the industrial origin of the later (Table 5). On the other hand,
strong relationship was found between methyl bromide, 1,2-
dichloropropane and 1,2-dicholoroethane (Fig. 7). Methyl bromide
is mainly used as soil fumigant for the control of nematodes, fungi
and weeds; it is also used in food-processing facilities (e.g. for
extracting oils from nuts, seeds and flowers). 1,2-Dicholorporpane
is still used as pesticide, although this practice is prohibited in
North America and Europe, it has also industrial use in the applica-
tion of paint, lacquers and varnishes and for manufacture of manychlorinated compounds. 1,2-Dicholoroethane has agricultural and
industrial applications, as chemical intermediate in the vinyl chlo-
ride monomer manufacture [38].
Finally, the concentrations of isoprene, the unique biogenic
VOCs measured, showed concentrations $1.0 ppbC in the urban
sites and lower than 1.0 ppbC in the suburban and rural sites. Its
higher level in the urban area may be the result of vehicular emis-
sions rather than vegetation, which is scarce in the city.
3.3. Meteorology
Before this work, no previous studies on local wind circulation
had been reported for this region. Meteorological measurements
were carried out to determine the occurrence and properties of lo-cal flow patterns, to examine the structure and evolution of the
mixing layer over the basin and to provide data for evaluation
and testing numerical meteorological models.
Three important parameters were determined at JR, SI and VS
sites to understand transport and dilution of pollutants in this re-
gion: the mixing layer height (MH), the transport velocity (TW)
and the ventilation index (VI) which is calculated as the product
of MH and TW. In general, the VI values assured good ventilation
conditions in the whole area in the afternoon. The highest mixing
layer height was observed at 1800, reaching mean values approx-
imately of 3300 m above ground level.
The frequent meteorological conditions are exemplified with
the data from March 5: synoptic winds aloft had strong influence
on the wind flow at lowest levels, wind direction above 3 km fromthe ground is similar for the three sites; below that level, wind
direction changes slightly along the column, reaching its maximum
difference on the surface level, varying from S at JR to SSW at SI
(Fig. 8a). This meteorological condition caused the transport of pol-
lutants out of the city. On the contrary, on March 9 (Fig. 8b), wind
direction below 1 km blew from NNE at JR and VS sites to ENE at SI
site, above that level wind changed constantly until it reached syn-
optic winds (SSW), 5 km above the ground, causing transport of air
masses into the city [39].
The potential temperature evolution along the day is an impor-
tant parameter that measures the dilution of pollutants. The fre-
quent conditions observed at 0800 at all sites showed that the
surface-based inversion formed overnight was partially elimi-
nated. At noon, the mixing layer height was above 1200 m at all
sites, and at 1800 the mixing layer was approximately between
3000 and 3500 m high. On March 9, the potential temperature
had a different behavior, at 0800 at all sites presented surface-
based thermal inversion, at noon the mixing layer was below
500 m, and at 1800 the mixing layer height reached the highest
values during the field campaign, above 4000 m.
3.4. Modeling of transport and dispersion of pollutants in the region
The Regional Atmospheric Model System (RAMS) and the CIT-
SAPRC99 models were used to simulate the physical and chemical
processes which control dispersion, transport and formation of
pollutants in the atmosphere. The study region was set to an exten-
sion of 140 140 km, divided into a grid of 74 74 tridimensionalcells with a resolution of 2 2 km. the Salamanca city was located
Table 5
Correlation coefficient (Pearson) for selected halocarbon species and VOCs in
Salamanca during FebruaryMarch 2003.
MTBE i-Butane Toluene
Freon-114 0.05 0.00 0.00
Methyl bromide 0.01 0.20 0.34
1,2-Dicloroethane 0.03 0.22 0.24
Methyl chlorine 0.09 0.18 0.21
1,2-Dicloropropane 0.04 0.37 0.71Diclorobenzene 0.00 0.04 0.06
Vinyl chlorine 0.24 0.72 0.88
R2
= 0.99
R2
= 0.99
0
10
20
30
40
50
60
70
0 10 20 30 40 50 60 70
ppbC
1,2 dochloroethane (ppbC)
1,2dichloropropane
methyl bromide
Fig. 7. Halogenated compounds in ambient air in Salamanca, Mexico. FebruaryMarch, 2003.
(a) March 5, 2003: 18 hrs
Wind Direction
Altitu
de(m)
0
1000
2000
3000
4000
5000
0 60 120 180 240 300 360
VS
SI
JR
(b) March 9, 2003: 18 hrs
Wind Direction
Altitude(m)
0
1000
2000
3000
4000
5000
0 60 120 180 240 300 360
VS
SI
JR
Fig. 8. Wind direction profiles at Silao (SI), Juventino Rosas (JR) and Valle de
Santiago (VS). (a) March 5, 2003; (b) March 9, 2003 both at 18:00.
3516 E. Vega et al./ Fuel 90 (2011) 35093520
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in the center of this region. The meteorological model RAMS was
used to calculate temperature, relative humidity, turbulence, wind
speed and wind direction every 300 s for each cell. The topography
and land use were taken into account for an adequate simulation of
surface wind pattern [19]. The photochemical model CIT-SAPRC99
was used to solve the transport and mass conservation of 112
chemical species using the SAPRC99 chemical mechanism [40].
Modeling results were used as complement tool to improve theunderstanding of tropospheric ozone behavior throughout the
study region where no measurements were available.
The CIT-SAPRC99 uses operator splitting technique to solve
transport and chemical processes separately in each time step. Ver-
tical diffusion is modeled as a function of atmospheric stability
class, with the mixing height entered as input to the model. The
model was modified to account for three-dimensional fields of
temperature and humidity as inputs, and to calculate reaction rates
in three dimensions on the basis of these parameters [20]. The CIT
model has been applied and tested extensively and reported else-
where [4144].
The CIT uses a terrain-following coordinate system and 15 ver-
tical layers were defined for this work, with the top boundary of
the modeling domain at 4628 m above the surface. The height of
each layer became smaller as it approached to the surface (e.g.
50 m for the lowest layer) for greater resolution. The wind fields
obtained from RAMS model were interpolated to fit the CIT-SAP-
RC99 grid domain, smoothed and filtered to improve mass consis-
tency in the CIT-SAPRC99 model.
The results obtained from the RAMS model indicated two differ-
ent dispersion conditions during the study period. The first and
more frequent condition showed circulation of winds during early
morning and night that converged towards the Salamanca city i.e.mountain-valley circulation (Fig. 9A). From 1000, the circulation
shifted towards the mountains (Fig. 9B) with a NW wind direction
at 1800 (Fig. 9C). After this time, the wind speed decreased and the
wind direction returned towards the city (Fig. 9D). The second less
frequent condition indicated a constant wind direction from the
NE, from 1000 to 2000 (not shown). Such meteorological condition
led to accumulation of emissions inside the valley and therefore
the increase of pollution levels.
The results of coupled application of RAMS and CIT-SAPRC99
models to estimate production and transport of ozone are illus-
trated in Fig. 10A-D, which describe ozone concentration indicated
with background colored from blue (0 ppb) to red (200 ppb), wind
fields (black arrows) and VOCs plumes (green zones) emitted from
Len, Irapuato, Salamanca and Celaya cities (L, I, S and C yellow let-
ters, respectively). Simulations were calculated for 0900, 1200,
(A) 0800. (B) 1000.
(C) 1800. (D) 2300.
Fig. 9. Surface wind field determined by RAMS model for the study region on March 4, 2003 at (A) 0800; (B) 1000; (C) 1800 and (D) 2300.
E. Vega et al. / Fuel 90 (2011) 35093520 3517
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1600 and 2100. Fig. 10A shows that wind flow at 0900 was domi-
nated by drainage flow of cold air descending from the mountains,
transporting urban emissions to the lowest areas of the region. Athis time of the day, high atmospheric stability conditions and ther-
mal inversion caused that emissions were trapped near the surface
and minimum ozone production. At noon, VOCs were diluted due
to the rapid growth of the mixing height, so only a small plume
is observed at L. Ozone production is evident in those regions
where precursors were transported to early in the morning, while
ozone concentrations were minimal in the urban areas. Fig. 10C
shows that wind pattern at 1600 has changed, transporting air
masses from southwest to northeast. The ozone formation was
well developed in the whole region and the maximum ozone con-
centrations were calculated in the NE of the models domain.
Again, at night (Fig. 10D), cold air descending from the mountains
began to dominate the wind circulation in the region. As expected,
the CIT-SAPRC99 predicted moderate ozone concentration (4060 ppb) remaining at surface level in the NE rural zones due to
insignificant of NOX sources in that region and again VOCs concen-
trations became significant at surface level in the urban zones.
The above described behavior was frequently observed in theregion, especially when weak synoptic conditions generated val-
ley-mountain circulation. Nevertheless, it is not possible to deter-
mine a general wind pattern due to the limited time of the
study; it would be necessary to carry out the analysis for other sea-
son of the year.
Finally, overall observed and modeled results of this survey
indicate environmental implications due to the exposition of pop-
ulation to secondary pollutants and halogenated hydrocarbons,
especially in the rural areas located northeast of the industrial
and urban zones. As a consequence of this study, local and federal
environmental authorities in collaboration with PEMEX (the Na-
tional Oil Company) and the Comisin Federal de Electricidad (Fed-
eral Electricity Bureau) developed the first Air Quality Program for
the region (20032006). Main achievements of this program werethe reduction in number of days with sulfur dioxide concentrations
(A) 0900. (B) 1200.
(C) 1600. (D) 2100.
L
I
S
C
Fig. 10. Hydrocarbon urban plumes (green) and ozone concentrations (from blue = 0 ppb to red = 200 ppb) modeled by coupled application of RAMS and CIT-SAPRC99 during
March 4 2003 in Salamanca region. (A) 0900; (B) 1200; (C) 1600 and (D) 2100. Arrows indicate surface winds. Panel A shows the location of cities: L = Leon; I = Irapuato;
S = Salamanca and C = Celaya. (For interpretation of the references to color in this figure legend, the reader is referred to the web version of this article.)
3518 E. Vega et al./ Fuel 90 (2011) 35093520
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above the standard, from 79 in 2003 to 34 in 2006. Later on, the
program included definitive removal of methyl bromide usage for
agricultural activities [24].
4. Conclusions
A 2-week field campaign of measurements of criteria pollutants,VOC and meteorological parameters was carried out during Febru-
aryMarch 2003 in the Salamanca city which is located inside one
of the most important industrial corridors of Mexico, to characterize
airqualityin theurban andregional scales. Special emphasiswas gi-
ven to the chemical characterization of VOC to gain knowledge
about levels, distribution and origin of these species. In spite of lim-
ited period of time, this monitoring effort currently represents one
of the biggest studies on airqualityrealized in Mexico, without con-
sideringthe mostrecent studies carried out in the metropolitan area
of Mexico City, which allows investigating the air quality condition
in an area highly influenced by industrial emissions.
Regarding one of the most important pollutants, the SO2showed a high concentration event at 0200 at the urban site, lo-
cated 2 km west of the Refinery and the Power Plant. The levels
of this pollutant reached 0.60 ppm (1 min sampling-time). Histor-
ically, extremely high levels of SO2 have been frequently observed
from 0000 to 0300 in the city, attributed to venting operations of
the Refinery and the Power Plant. However since 2003 control
measurements have been implemented to reduce levels of SO2and particles in the atmosphere, such as the shifting to cleaner
fuels (with lower content of S) in both the Power Plant and the
Refinery. These measurements were already in execution by the
time of the field campaign, thus it is possible that the first positive
results were observed.
The highest ozone levels were observed in the rural monitoring
sites, which are explained by transport and possible inputs from
the free troposphere, given the high altitude of the study region.
Total VOCs mass concentration fluctuated from 170 ppbC in the
rural area to 956 ppbC in the urban sites. The more abundant groupwas the alkanes followed by aromatics, olefins and halogenated.
The total mass concentration of VOCs is comparable with
values reported for some urban and rural sites of Mexico City
Metropolitan Area. However, the concentration of halogenated
species (particularly Freon-114, methyl bromide, 1,2-dichloroeth-
ane and 1,2-dichloropropane) was notoriously higher in rural sites
of Salamanca compared with Mexico City and other highly polluted
areas of China. Formaldehyde and acetaldehyde showed average
concentrations of 4.3 and 2.7 ppb, respectively which are lower
than those reported for Mexico City (13.3 and 4.4 ppb respec-
tively). Due to these low values, it is expected little contribution
of carbonyl species to the photochemical activity in the region.
The origin of VOCs was inferred by examining the concentration
and spatial distribution of species, in conjunction with cross corre-lation analyses and relationship of marker species for specific
sources. In the urban area, gasoline and diesel vehicular exhaust
and marketing/leaking of LPG dominated the VOCs burden, while
emissions from industrial and agriculture activities were impor-
tant in the rural area. The last two sources emit halogenated spe-
cies that represent potential hazard to human health due to the
toxic and/or carcinogenic effect, thus the results of this study high-
lighted the needed of monitoring and even implementing control
measurements for these species. As a consequence, federal and lo-
cal environmental authorities removed usage of methyl bromide in
agricultural activities since 2007.
Meteorological conditions generally favoured the transport of
pollutants outside Salamanca towards northeast, where the high-
est concentration of ozone were observed. This result was in agree-ment with the modeling calculations.
Acknowledgements
This study was supported by Mexico national oil company
(PEMEX) under contract IMP-ZC-001-2003. The authors are grate-
ful to the authorities of Salamanca refinery by their help and sup-
port provided during the study.
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