synthesis of oxymethylene ethers
TRANSCRIPT
Synthesis of Oxymethylene Ethers
Dissertation
Zur Erlangung des akademischen GradesDoktor der Naturwissenschaften (Dr. rer. nat.)
vorgelegt an der Fakultät für Chemie und Biochemieder Ruhr-Universität Bochum
von
Anna Grünert
BochumOktober 2019
Die vorliegende Arbeit wurde in der Zeit von Februar 2016 bis Oktober 2019 in der Abteilung
für Heterogene Katalyse am Max-Planck-Institut für Kohlenforschung in Mülheim an der
Ruhr unter der Leitung von Prof. Dr. Ferdi Schüth angefertigt.
Referent: Prof. Dr. Ferdi Schüth
Korreferent: Prof. Dr. Martin Muhler
I
I Acknowledgements
Firstly, I would like to thank my team of supervisors, Prof. Dr. Ferdi Schüth andDr. Wolfgang Schmidt, and my co-examiner Prof. Dr. Martin Muhler.
Ferdi, I would like to thank you for your trust that is the basis of the exceptionalfreedom of work, which you grant not only to me, but to all of your PhD students. Yougave me the resources, time and liberty to develop my PhD project in my own way, tomake mistakes, to solve challenging problems and to grow as a person. I am gratefulfor your appreciation of a cooperative and welcoming atmosphere in the group, whichis most apparent in your yearly invitation to the group trip to Oberwesel.
Wolfgang, I owe my thanks to you for your advice on many topics including materialsynthesis, catalyst characterisation and manuscript writing. I very much appreciateyour welcoming and relaxed attitude.
I am also thankful that to you both that you enjoy sharing your knowledge andexperience with me and my colleagues in catalysis seminars and other technicalseminars and in the focused project meetings.
Prof. Muhler, thank you for taking interest in my work and for agreeing to be theco-examiner.
The practical realisation of this work would not have been possible without the help of thestaff of service departments, the technical staff of Schüth group and fellow PhD students.
This is why I feel fortunate to have worked in close cooperation with the team of theFeinmechanics workshop including Wolfgang Kersten, Dirk Ullner, Knut Gräfenstein,Jürgen Majer, Sebastian Plankert and Ralf Thomas. Big thanks to all of you for yourtechnical support and your exceptional willingness to help students in building andmaintaining catalytic test equipment.
Dirk, thank you so much for your fast and competent support when my set-up gave metroubles. It was also a pleasure to learn about set-up design, properties of steels andother materials and to get an introduction to the tools used in the workshop. Knut andDirk, I will truly miss your ability to cheer me up with your special humour. I alwaysfelt welcomed at the Feinmechanics workshop.
I would also like to acknowledge the contributions of locksmith and glassblowerworkshops to my project.
In the pressure lab, where my catalytic test set-up was located, Nils Theyssen, NiklasFuhrmann and Lars Winkel made sure that everyday operation of set-ups and lab
II
infrastructure ran smoothly. I owe my thanks to you and to my box neighbours ReneAlbert, Dr. Robert Urbanczyk, Kateryna Peinecke and Özgül Sener for regularlyhelping me out with technical advice and spare parts.
In the main lab, the technical staff André Pommerin, Laila Sahraoui and Flo Baum andtheir team of apprentices made sure that the lab was always safe and functional. Thankyou for being approachable and helpful and for knowing where to find all kinds ofthings.
I also owe many thanks to the staff of NMR, electron microscopy, HPLC, GC and ITdepartments including Dr. Bodo Zibrowius, Silvia Palm, Georg Breitenbruch, FrankKohler, Philipp Schulze, Marjan Tomas and Marcus Hermes.
I learned a lot from my colleagues Dr. Nicolas Duyckaerts, Dr. Ioan-Teodor Trotus,Dr. Daniel Wendt, Dr. Cristina Ochoa-Hernández, Dr. Pit Losch and Hrishikesh Joshi.
Nico, Teo and Daniel, thank you for your patience in sharing your knowledge aboutSwagelok, flow set-ups and reactors. I am grateful for your input regarding the designand assembly of my test set-up at the beginning of my PhD project. Cristina, Pit andHrishi, I appreciated your interest in my project and our fruitful discussions aboutchemistry.
Of course, there is more to a PhD than working in the lab. I feel thankful for having gotten toknow so many inspiring, kind and open fellow researchers. You have made me feel deeplyconnected to this group and have made my PhD time very enjoyable.
I would like to express my gratitude towards my colleagues Özgül Agbaba Sener, ReneAlbert, Dr. Ghith Al-Shaal, Dr. Amol Amrute, Alex Bähr, Adrian Barranco, TugceBeyazay, Marius Bilke, Alex Bodach, Joel Britschgi, Eko Budiyanto, Dr. MatthewClough, Dr. Yitao Dai, Dr. Isabel de Freitas, Jacopo de Bellis, Dr. Michael Dierks,Dr. Georgios “Jorro” Dodekatos, Dr. Rene Eckert, Dr. Michael Felderhoff, JessicaGonzález, Alexander Hopf, Dr. Daniel Jalalpoor, Kai Jeske, Hrishikesh Joshi,Dr. Marco Kennema, Dr. Jonglack Kim, Klara Kley, Dr. Pit Losch, Dr. Gun-HeeMoon, Dr. Valentina Nese, Edward Nürenberg, Dr. Cristina Ochoa-Hernández, EzgiOnur Sahin, Dr. Seyma Ortatatli, Dr. Jochen Ortmeyer, Kateryna Peinecke, Dr. HilkePetersen, Dr. Christian Pichler, Dr. Gonzalo Prieto, Steffen Reichle, Dr. BidyutSarma, Dr. Hannah Schreyer, Dr. Stefan Schünemann, Niklas Stegmann, Dr. HarunTüysüz, Dr. Robert Urbanczyk, Dr. Olena Vozniuk, Dr. Claudia Weidenthaler,Frederik Winkelmann, Mingquan Yu and all other colleagues that I may have forgottento mention.
III
Thank you for spending time with me in the lab, at Mensa, in the social room, at lunchgroup, at group and cake seminars and other social events. Also, I am glad that some ofyou never forgot how to celebrate and dance.
Edward, Niklas, Alex, Özgül and Cristina, it was great to share an office with you. Ihave appreciated the focused working atmosphere on the one hand and your opennessto share matters of every-day life on the other hand. Thank you for your moral supportand your valuable advice.
Annette Krappweis und Kirsten Kalischer, your assistance in organisational issues wasof great help.
For financial support of my PhD, I would like to acknowledge the Max Planck Society andFonds der chemischen Industrie.
My participation in the JungChemikerForum Mülheim during my time at the Max-Planck-Institut für Kohlenforschung was also a great experience. It made me feel more connected tocolleagues from the other research groups of this institute
Minh Dao, Lorenz Löffler, Jonas Börgel, Jens Rickmeier, Suzanne Willems, FabioCaló, Christine Schulz, Tobias Biberger, Julius Hillenbrand, Van Anh Tran, MarcHeinrich, Sebastian Beeg, Simon Musch, Christina Erken and those that I unfortunatelyforgot to mention, I would like to thank you for great team work and for your trustwhen I was your speaker.
Last, but not least, I would like to express my gratitude towards my parents Wolfgang andTanja Grünert and my partner Arne Schüttler. They have supported me during my bachelor’sand master’s degree and during my PhD project.
Dad, thank you for passing on your appreciation for sciences, literature and music andespecially for sharing your passion for chemistry.
Mum, thank you for your unconditional moral support in all situations and for teachingme openness and curiousness.
Arne, thank you for sharing your daily life with me, including its challenges and joyfulmoments. I am deeply grateful for your continuous trust and encouragement over theyears.
IV
V
II Table of contents
I Acknowledgements ............................................................................................................. III Table of contents ................................................................................................................ VIII Abbreviations ................................................................................................................. VIII1 Thesis abstract ..................................................................................................................... 12 Introduction ......................................................................................................................... 2
2.1 Synthetic fuels ........................................................................................................... 22.1.1 Chemical CO2 recycling .................................................................................... 22.1.2 Drop-in fuels ...................................................................................................... 32.1.3 Reduction of diesel emissions ............................................................................ 4
2.2 Oxymethylene ethers ................................................................................................. 52.2.1 Physicochemical and fuel related properties of OME ....................................... 52.2.2 Development and future challenges of OME research ...................................... 72.2.3 Synthesis ............................................................................................................ 8
2.3 Solid acid catalysis .................................................................................................. 122.3.1 Zeolites ............................................................................................................. 132.3.2 Supported liquid phase catalysts ...................................................................... 162.3.3 Characterisation methods ................................................................................. 18
2.4 Methanol dehydrogenation ...................................................................................... 202.4.1 Oxidative vs. non-oxidative route .................................................................... 202.4.2 Catalysts ........................................................................................................... 21
3 Motivation and research objectives ................................................................................... 234 Description of test set-up ................................................................................................... 25
4.1 Concept ................................................................................................................... 254.2 Technical implementation ....................................................................................... 26
4.2.1 Gas and pressure control .................................................................................. 274.2.2 Evaporator unit ................................................................................................ 274.2.3 Heating ............................................................................................................. 284.2.4 Reactor ............................................................................................................. 28
4.3 Product analysis ...................................................................................................... 294.4 Safety features ......................................................................................................... 304.5 Extensions for combined process ............................................................................ 31
5 Screening of reaction conditions ....................................................................................... 335.1 Temperature ............................................................................................................ 335.2 Pressure ................................................................................................................... 365.3 Reactant ratio .......................................................................................................... 37
VI
5.4 Water content .......................................................................................................... 385.5 Pellet Size ................................................................................................................ 385.6 Catalyst activation protocol .................................................................................... 385.7 Reproducibility ....................................................................................................... 39
6 Preliminary catalyst screening .......................................................................................... 407 OME synthesis over zeolite catalysts ................................................................................ 42
7.1 Catalyst screening ................................................................................................... 427.2 Correlation between acid site properties and catalyst performance ........................ 437.3 Influence of particle size and external surface area ................................................ 497.4 Adaptation of reaction conditions ........................................................................... 507.5 Catalyst deactivation and regeneration ................................................................... 517.6 Comparison of siliceous materials .......................................................................... 527.7 Conclusions ............................................................................................................. 54
8 OME synthesis over supported phosphoric acid ............................................................... 558.1 Catalyst Characterisation ........................................................................................ 568.2 Preliminary studies of exemplary H3PO4/C catalyst ............................................... 598.3 Impact of H3PO4 loading ........................................................................................ 608.4 Sodium phosphates ................................................................................................. 618.5 Comparison with benchmark zeolite ...................................................................... 638.6 Conclusions ............................................................................................................. 65
9 Two-step synthesis of OME from methanol ..................................................................... 669.1 Thermal decomposition of formaldehyde ............................................................... 679.2 Catalyst screening ................................................................................................... 689.3 Combined process ................................................................................................... 71
10 Summary and final remarks .............................................................................................. 7411 Experimental ..................................................................................................................... 76
11.1 Commercial materials ............................................................................................. 7611.1.1 Gases ................................................................................................................ 7611.1.2 Chemicals ........................................................................................................ 7611.1.3 Catalysts and other solid materials .................................................................. 77
11.2 Synthesis of catalysts .............................................................................................. 7811.2.1 Supported silicotungstic acid ........................................................................... 7811.2.2 SBA-15-SO3H ................................................................................................. 7811.2.3 Silicalite-1 ........................................................................................................ 7811.2.4 Supported phosphoric acid .............................................................................. 7911.2.5 Methanol dehydrogenation catalysts ............................................................... 79
11.3 Modification procedures ......................................................................................... 8011.3.1 Catalyst activation ........................................................................................... 80
VII
11.3.2 Sodium exchange of zeolites ........................................................................... 8011.3.3 Oxalic acid treatment of zeolites ..................................................................... 8111.3.4 Regeneration protocols .................................................................................... 81
11.4 Characterisation methods ........................................................................................ 8111.4.1 X-ray powder diffraction (PXRD) ................................................................... 8111.4.2 Temperature programmed desorption of ammonia (NH3-TPD) ...................... 8111.4.3 Pyridine adsorption followed by FTIR spectroscopy (Py-FTIR) .................... 8211.4.4 Magic-angle spinning nuclear magnetic resonance (MAS-NMR) .................. 8211.4.5 Thermogravimetric analysis coupled with mass spectrometry (TG-MS) ........ 8211.4.6 Diffuse reflectance infrared spectroscopy (DRIFTS) ...................................... 8311.4.7 Nitrogen physisorption .................................................................................... 8311.4.8 GC-MS ............................................................................................................. 8311.4.9 Scanning electron microscopy (SEM) ............................................................. 8311.4.10 Energy dispersive X-ray spectroscopy (EDX) ................................................. 8311.4.11 Transmission electron microscopy (TEM) ...................................................... 8411.4.12 Elemental analysis ........................................................................................... 84
11.5 Batch reactions ........................................................................................................ 8411.6 Wet-chemical analysis methods .............................................................................. 84
11.6.1 Preparation of methanolic formaldehyde solution ........................................... 8411.6.2 Iodometry ......................................................................................................... 8411.6.3 Karl-Fischer titration ........................................................................................ 85
12 Appendix ........................................................................................................................... 8613 References to laboratory journal entries .......................................................................... 10114 References ....................................................................................................................... 104
VIII
III Abbreviations
Table 1.1: Abbreviations.
ALPO aluminophosphates pKa negative logarithm of aciddissociation constant
BET Brunauer-Emmett-Teller PM particulate matter
CI compression ignition POM polyoxymethylene (polymer)
Xmax maximum conversion POMDME polyoxymethylene dimethyl ethers
DME dimethyl ether PXRD X-ray powder diffraction
DRIFTS diffuse reflectance infraredspectroscopy
rpm revolutions/rotations per minute
EDX energy dispersive X-rayspectroscopy
S selectivity
EFAl extra-framework aluminium SAPO silicoaluminophosphates
FA formaldehyde SAR silica-to-alumina ratio
FID flame ionization detector SEM scanning electron microscopy
FTIR Fourier transform infrared(spectroscopy)
SI spark-ignition
GC gas chromatography orgas chromatograph
SILP supported ionic liquid phase
GHG greenhouse gas Si-OH silanol group
HC hydrocarbons SLP supported liquid phase
HPA heteropoly acid Smax maximum selectivity
HPLC high-performance liquidchromatography
SPA phosphoric acid supported on silica
IR infrared STP standard temperature and pressure
Ka dissociation constant synair synthetic air
MAS magic angle spinning T in TO4 metal in tetrahedral oxygenenvironment
MeOH methanol TCD Thermal conductivity detector
IX
MFC mass flow controller TEM transmission electron microscopy
mol% mole fraction TG thermogravimetric analysis
MS mass spectrometry TPD temperature programmeddesorption
NMR nuclear magnetic resonance TRI trioxane
NOx nitrogen oxides WHSV weight hourly space velocity
OME oxymethylene ether wt% mass fraction
PF paraformaldehyde
1 Thesis abstract
1 Thesis abstract
Oxymethylene ethers (OME) are a class of chain ethers that have been classified as pollutant
reducing synthetic diesel additives in the late 1990s. In view of growing efforts to reduce
hazardous emissions from the transport sector and to find alternatives to fossil-based fuels,
OME have seen a rise in academic and industrial interest. Various synthesis routes that have
methanol as a common intermediate have been reported. However, the production remains the
main challenge for introduction of OME as a synthetic fuel.
This work explores the gas-phase synthesis of OME from methanol and formaldehyde as an
alternative approach to common liquid-phase routes. In particular, the investigation of solid
catalysts for this reaction is the focus of the conducted studies.
For this purpose, a versatile test set-up was built and suitable reaction conditions were
identified. The comparison of a selection of solid acid catalysts highlighted the activity of
zeolites in gas-phase OME synthesis. In a systematic study of a broad range of zeolite
catalysts, a relation between catalyst reactivity and silica-to-alumina ratio was established. It
could be shown that low amounts of acid sites are favourable for OME selectivity and that
strong acid sites are linked to by-product formation. Carbon supported phosphoric acid was
furthermore found to be an active catalyst for the gas-phase synthesis of OME with a superior
lifetime as compared to benchmark zeolite catalysts. Steady-state conversion and selectivity
were comparable at the same loading of active centres. In view of the simple preparation and
low cost of H3PO4/C, it provides an attractive alternative to zeolites. In a final step, the
viability of the gas-phase synthesis of OME from methanol without separation of
intermediates was demonstrated.
Introduction 2
2 Introduction
The aim of this chapter is to give background information that is relevant in the context of this
work on gas-phase synthesis of oxymethylene ethers, including socio-economic
considerations, properties of OME and catalysts, and state of the art of synthetic procedures,
production processes and characterisation techniques.
Firstly, the importance of research on synthetic fuels in general and the potential positive
contribution to the development of our future transportation sector will be discussed in chapter
2.1. Secondly, oxymethylene ethers as a promising class of synthetic fuels will be introduced
in chapter 2.2 with a focus on the development of OME research, physicochemical and fuel-
related properties as well as synthetic routes. As the investigations presented in this thesis rely
on solid acid catalysis, the two solid acid classes mainly employed in this work, namely
zeolites and supported phosphoric acid, will be presented in chapter 2.3 with an emphasis on
acid properties. Owing to the broad range of techniques available for acid characterisation, an
overview highlighting advantages and limits of the methods is also included. Finally, the
partial methanol dehydrogenation is a relevant intermediate reaction for a potential OME
synthesis from carbon dioxide (CO2) feedstock. Related reaction characteristics and catalyst
classes are summarised in chapter 2.4.
2.1 Synthetic fuels
In the research field of synthetic fuel, the academic and industrial interest is mainly driven by
socio-economic and health related aspects. These include the potential reduction of
anthropogenic CO2 emissions by large scale usage of CO2 as a feedstock for synthetic fuels as
discussed in chapter 2.1.1. Furthermore, the facilitated implementation of liquid synthetic
fuels as so-called drop-in fuels using existing infrastructure is reviewed in chapter 2.1.2. A
third important aspect highlighted in chapter 2.1.3 is the potential of emission reducing
synthetic fuels to alleviate health issues related to air pollution.
2.1.1 Chemical CO2 recycling
In current research, many efforts are directed towards mitigation of CO2 emissions and
development of CO2 recycling and storage strategies. This interest is sparked by the goal to
diminish the effect of global warming. The latter is the amplification of the naturally occurring
greenhouse effect by emission of greenhouse gases (GHG) such as carbon dioxide, methane
3 Introduction
(CH4), nitrous oxide (N2O) and fluorinated compounds from anthropogenic sources. CO2 is
rated to have the largest impact on global warming with 76% of total anthropogenic GHG
emissions.1
The transformation of CO2 to synthetic fuels can be classified as a CO2 recycle approach.
While CO2 can also be recycled and used for the production of chemicals such as urea,
salicylic acid and polycarbonates, its transformation to fuels can have a greater leverage owing
to larger fuel demand.2 Synthetic fuels can contribute to CO2 reduction from the transport
sector, which accounted for 23% of global CO2 emissions in 2013. More specifically, fuels
have a major impact in the road sector that represented a three quarters share of the transport
emissions and was driving its growth.1, 3
As of today, most synthetic fuels are still produced from fossil feedstocks such as mineral oil,
natural gas and coal. However, processes for the supply of CO2 as a feedstock by isolation
from industrial exhaust gases, biomass or via direct air capture are currently in development.4
Hydrogen is also required for the valorisation of CO2. Similarly, environmentally benign
processes for its production are not employed in large scale yet, but water electrolysis is a
viable approach. Interestingly, the recent drop in electricity prices from renewables has
sparked economical interest in power-to-liquid technologies. For example, a Norwegian
company is targeting to produce synthetic “e-diesel” from electrolysis hydrogen and recycled
CO2 in industrially relevant quantities from 2020 based on hydro powder.5
2.1.2 Drop-in fuels
When discussing CO2 based synthetic fuels in general, methanol (MeOH), dimethyl ether
(DME), higher alcohols, hydrocarbons and oxymethylene ethers (OME) are of importance. It
is necessary to consider the different requirements towards distribution infrastructure and
combustion in engines. While DME is a suitable fuel with regards to many important engine
related parameters, its gaseous state of matter at standard conditions requires adaptation of
infrastructure and vehicles to liquefied gas handling.6 It is argued that drop-in fuels, which are
liquid synthetic fuels that can directly substitute conventional fuels with only minor
modifications, will have a lower market introduction barrier. Also in the long run, the
development of non-fossil based liquid fuels will be important for applications that cannot
easily be equipped with pressurized tanks, batteries or fuel cells, for example aviation and
marine transport.
Introduction 4
In road transportation, spark-ignition (SI) and compression ignition (CI) engines are
commonly used. In terms of efficiency, operating cost and CO2 emission per distance
travelled, the diesel fuelled CI engine is clearly favourable.7, 8 For CI engines, hydrocarbons
and oxymethylene ethers (OME) are the most prominent examples for synthetic drop-in fuels
that can potentially be produced on the basis of CO2 feedstock. Hydrocarbons can be
synthesised via the Fischer-Tropsch process. Information of the synthesis of OME will be
supplied in chapter 2.2.2. In comparison to Fischer-Tropsch diesel, OME have two interesting
additional advantages, namely the low toxicity and the pollutant reducing properties as
discussed in the following section.
2.1.3 Reduction of diesel emissions
Even though technologies such as battery or fuel cell powered vehicles are emerging, internal
combustion engines still dominate road transport worldwide and will certainly continue to
represent a large share of vehicles also in the medium-term. It is therefore interesting to
analyse the impact of internal combustion engines on the environment and approaches to limit
harmful effects.
As mentioned above, compression ignition engines outperform spark-ignition engines in terms
of efficiency, operating cost and CO2 emission per distance travelled.7, 8 However, a major
disadvantage is increased exhaust gas pollutant emissions from CI engines. Emitted pollutants
include mainly particulate matter (PM, soot) and nitrogen oxides (NOx) as well as lower
amounts of carbon monoxide (CO) and hydrocarbons (HC). Particle emissions from diesel
engines are 6-10 times higher than from gasoline engines.7
The pollutants pose a severe risk to the human health as they can cause heart and lung diseases
as well as strokes. According to the World Health Organization, 4.2 million premature deaths
per year are a consequence of ambient air pollution.9 Further adverse effects include acid rain,
ground-level ozone and reduced visibility.
Legislation dealing with air pollutants has been developing towards lower emission levels in
many countries worldwide.10 In this context, approaches to reduce pollutants from road
transport have gained in importance.11 Common strategies include engine improvements and
exhaust aftertreatment. For exhaust gas treatment of CI engines, diesel oxidation catalyst for
removal of CO and HC, particulate filters and catalytic abatement of nitrogen oxides (selective
catalytic reduction (SCR) and nitrogen storage and reduction (NSR)) can be applied.7, 12 In
5 Introduction
addition to the mentioned routes, potential also lies in reducing the initial formation of
pollutants by using emission reducing fuel additives and clean burning synthetic fuels.
Emission reducing diesel additives are mainly hydrocarbon compounds that contain oxygen
functionalities and are referred to as oxygenates.8 For SI engines methanol, ethanol and
methyl-tertbutyl ether can be used.13 These are however not suitable for CI engines due to
fundamentally differing working principles and therefore differing requirements for diesel
fuels. For CI engines, oxymethylene ethers (OME) are particularly suitable owing to their
pronounced pollutant reducing effect and favourable physicochemical properties.
2.2 Oxymethylene ethers
2.2.1 Physicochemical and fuel related properties of OME
OME are a series of homologous chain ethers with the chemical formula CH3O(CH2O)nCH3 ,
n denoting the length of the central ether chain in the abbreviation OMEn (see Figure 2.1).
Figure 2.1: Chemical structure of oxymethylene ethers, n denoting the number of repeating units.
With regards to chemical stability, OME are stable in alkaline and neutral medium and are
hydrolysed under acidic conditions as other acetal containing compounds. Their
physicochemical properties depend on chain length (see Table 2.1). With increasing length,
boiling and melting point, density, cetane number, flash point, viscosity, surface tension, and
oxygen content increase.6, 14, 15
Table 2.1: Selected physicochemical and fuel properties of OME1-5.14, 16
OMEn
oligomeroxygencontent(wt%)
density at20 °C
(g/cm3)
meltingpoint(°C)
boilingpoint(°C)
flashpoint(°C)
cetanenumber
OME1 42.1 0.868 -105 42 -32 28OME2 45.2 0.971 -70 105 16 68OME3 47.0 1.035 -43 156 54 72OME4 48.1 1.079 -10 202 88 84OME5 48.9 1.111 18 242 115 93
Introduction 6
OME1, also referred to as dimethoxymethane or methylal, is the shortest homologue and is a
well-established solvent used for industrial applications in plastics and perfume industry17, 18
as well as in organic synthesis.19 Its industrial production is commonly based on reactive
distillation from methanol and aqueous formaldehyde solution.20-23 With respect to its use as
fuels, OME1 and OME2 are more volatile than conventional diesel, but could be used in
modified devices.15, 24 Owing to its low flash point, OME2 has a potential application as a pilot
fuel for methanol based spark-ignition engines.25
The physicochemical properties of the intermediate length homologues OME2-5 fulfil fuel
requirements fully, such as flash point and cetane number, or partially, for example lubricity,
kinematic viscosity and surface tension.14, 26 Due to the increased melting points of OME
chains with more than five repeating units, the risk of precipitation in the engine makes those
homologues unsuitable for use as fuel. Hence, OME2-5 or OME/diesel blends are regarded as
potential drop-in fuels that could be used in conventional motors with only minor adjustments
as highlighted in chapter 2.1.2.4
Owing to the oxygen content, the heating value of OME is lower than of diesel fuel (higher
heating value of OME3-5: approx. 21 MJ/kg, diesel: approx. 45 MJ/kg).14 This results in higher
gravimetric fuel consumption. The increase in volumetric fuel consumption will however be
less pronounced, due to the higher density of OME.
As mentioned in chapter 2.1.3, a major advantage of oxygenates are the pollutant reducing
properties. These were identified and patented by Moulton and Naegeli.24, 27 The most
pronounced reduction is achieved with regards to soot and particulate matter as has been
demonstrated for OME124, 28-31 as well as OME2-56, 32-40 by various research groups. It is
reasoned that neat OME combusts nearly soot-free due to lack of C-C bonds.41-43 While the
absolute values of soot reduction depend on blends, reference fuel, operating points and
engine type,28 it is evident that the soot reducing properties are not solely an effect of diesel
substitution. For example, for a diesel blend containing 20% OME3-4, a decrease in soot
emission of 60% and decrease in particulate mass by 40% in raw emissions of a six-cylinder
engine without after-treatment was reported.6 Due to reduced soot formation, engine
parameters such as exhaust gas recirculation can be adjusted in a wider range, allowing to
decease also harmful NOx emissions.31, 38
7 Introduction
An additional general benefit of OME are the high cetane numbers, which can improve engine
efficiency.14 Cetane numbers of OME>1 are significantly higher than the defined lower limit of
51 (see Table 2.1).26 Finally, full miscibility of OME with diesel fuel and its low toxicity are
advantageous.18
2.2.2 Development and future challenges of OME research
The description of chain ethers with the chemical formula CH3O(CH2O)nCH3, referred to as
oxymethylene ethers (OME) or polyoxymethylene dimethyl ethers (POMDME), reaches back
as far as 1904, when Descudé reported the synthesis of OME2 from sodium methylate and
dichloro dimethyl ether.44 In the 1920, Staudinger published works on oligomeric and
polymeric OME with the aim of understanding the nature of polymeric materials.45 The first
patent on synthesis of oligomeric OME was assigned to DuPont in 1948.46 Of commercial
relevance was the development of production processes for polymeric homologues of OME.
These are named polyoxymethylene (POM) or polyacetals and were commercialized by
DuPont in the 1960s.47 POM is a thermoplastic polymer with high mechanical, thermal and
chemical resistance and is mainly applied in the automotive and electronics sectors. In the
following years, further studies on properties of short chain OMEs were published.48-50 For
example, Boyd reported physical properties, such as vapour pressure, density, melting points
of the homologues OME1-4 in 1961.51
More recently, the main research interest in oligomeric OME is based on the finding that
oxygenates have favourable combustion properties as mentioned in chapter 2.1.3.8 In a
potential chemical production network based on methanol as a platform chemical as proposed
by Olah,52 OME could furthermore be attractive components.
Since 1997, when OME was found to have favourable properties for combustion in CI
engines,27 several companies have filed patents for the synthesis of OME as diesel additives,
such as BP Amoco Corporation53, 54 and BASF.55, 56 OME are also of particular interest to
Chinese companies that have filed numerous patents in the past years. Relying on its large
reserves in coal, synthesis gas based chemical industry has strongly developed in China, and
an oversupply of methanol has been observed.57, 58 In this context, OME could help to balance
changes in supply of diesel fuel. In 2015, the first and currently the only large-scale OME
plant was installed by Shandong Yuhuang Chemical Company in China.
Introduction 8
In terms of application development, it is interesting to note that the viability of OME for use
in conventional cars was demonstrated in 2017. The automotive manufacturing company
Continental successfully employed OME blends in test vehicles.59 Moreover, engineers from
TU Darmstadt retrofitted a standard car to run on neat OME fuel.60
The major challenge remains the economically feasible production of OME. The predicted
price of OME fuel depends strongly on variables, such as choice and price of raw materials
and the considered synthesis route.61, 62 With current technology and prices of raw materials,
OME are estimated to be 2-4 times more expensive than conventional diesel fuel.5, 60 In the
current synthesis process, 60% of the production cost are attributed to raw materials, while
energy demands are considered to account for 20% of the final OME price.61 To date, OME
are produced with an energy use as high as 10 MJ/kg OME in the Chinese production
facility.63, 64 This results from the energy-intensive production and separation of the
intermediate trioxane and OME1.
It is evident, that process development will be a key factor to realise wide-spread use of OME
as diesel additive or fuel. In this context, the in-depth study of the catalytic transformations
involved in OME formation is an interesting and relevant field of research.
2.2.3 Synthesis
The general formula CH3O(CH2O)nCH3 shows that OME are built from a chain of
formaldehyde-derived repeating units (CH2O)n and methyl end-groups. As pure monomeric
formaldehyde is not commercially available as a reagent due to its tendency to polymerise, it
needs to be introduced into the reaction via either paraformaldehyde (PF), trioxane (TRI) or in
solution. PF represents uncapped formaldehyde polymer chains, while TRI is a trimer of
formaldehyde. The monomeric formaldehyde is released via acid-catalysed or thermal
decomposition. Aqueous or methanolic formaldehyde solutions contain mainly short-chain
poly(oxymethylene) glycols or hemiformals, respectively, which are in equilibrium with
monomeric FA and readily react.65 There are also several options for supplying the end-group.
Methanol (MeOH), dimethoxymethane (OME1) and dimethyl ether (DME) are options for
capping agents.
An exemplary reaction scheme for the reactant combination methanol and formaldehyde is
depicted in Figure 2.2. It includes hemiformal formation, chain-growth and acetal formation
steps. The reaction steps are reversible and the presence of water can shift the equilibrium
9 Introduction
towards the hemiactals.66 The presence of water in the reaction has been described to reduce
reaction rate and OME selectivity in various liquid-phase batch experiments.67-69
Figure 2.2: Schematic representation of OME formation from methanol and formaldehyde.
Analogous to other chain-growth reactions, a product distribution of different homologues is
obtained. It follows a Schulz-Flory distribution, which has been developed to describe
molecular weight distributions of linear condensation polymers.67, 70-72 In literature, no
conclusive indications are available on whether chain-growth in OME formation occurs via
oligomeric hemiformals (initiation, growth and termination mechanism) or via insertion of
formaldehyde into OMEn (sequential mechanism). It is suggested that the mechanism depends
on reactants and reaction conditions. Commonly, the probability of chain growth is observed
to be low in acid catalysed synthesis which leads to product distributions mainly comprised of
short-chain OME.64
The different reactant combinations can be classified according to the reaction
characteristics.64 Reactant combinations of methanol with any formaldehyde source are called
aqueous route as water is a stoichiometric side-product in the acetal formation step. In
aqueous synthesis mode, poly(oxymethylene) glycols and hemiacetals are potential by-
products. Also the combination of OME1 and PF is classified as aqueous, as low amounts of
water are released upon depolymerisation of PF. In contrast, no water is formed when OME1
is reacted with TRI. This route is hence called anhydrous route. Current industrial processes
are based on the latter route. Also the recently described reaction of DME with TRI is an
anhydrous transformation.73
As OMEs synthesis is in general a catalytic transformation, the various proposed synthetic
procedures can also be classified according to the catalysts used.
Introduction 10
Homogeneous catalysis involving mineral acids55 and acidic ionic liquids74-76 can be applied
for the above described reactant combinations. Additionally, recent reports of OME1
formation from CO2, H2 and MeOH over organometallic catalysts in solution77, 78 and of OME
formation from OME1 and absorbed gaseous FA catalysed by trimethyloxonium salts79 can be
assigned to this group.
A broad range of synthetic procedures involving heterogeneous catalysis have been reported.
As this work is focussed on solid catalysts for OME formation, this class will be described in
more detail below. Also methods for direct synthesis of OME1 via either one-step oxidation of
MeOH80-90 or via DME oxidation91-94 are based on heterogeneous catalysis. Mainly transition
metal oxide containing solid catalysts and materials based on supported heteropoly acids have
been reported in this context.
As mentioned above, a wide range of synthetic procedures involving solid acid catalysts has
been published in the scientific literature. Table 2.2 gives an overview of the reported reaction
parameters, such as reactant combination and ratio, catalyst type and loading, reaction
temperature and time. Additionally, the maximum conversion and OME selectivity reported
are specified. Table 2.2 is limited to batch-mode reactions, which constitute the majority of
reports in the scientific literature. The various solid acid catalysts listed include ion-exchange
resins, zeolites, alumosilicates, sulphated metal oxides, graphene oxide as well as supported
ionic liquids and stabilized heteropoly acids.
When comparing the catalyst performance data summarized in Table 2.2, it is necessary to
consider the following aspects: In case of OME1 as a capping agent, OME1 is commonly
regarded solely as a reactant, while in case of the capping agent MeOH, OME1 is one of the
products and is hence also considered in the calculation of selectivity. The maximum
attainable selectivity of homologues longer than OME1 will therefore differ. It is also not
consistently specified whether selectivity is given in mol% or wt% within the reports.
Additionally, the selectivity towards different OME homologues is lumped into varying
groups. The feasibility of a direct comparison of the reported data is hence limited.
In addition to liquid-phase batch-reactions, flow reactions were mainly described in patent
literature. In the context of this work, processes based on methanol and formaldehyde as
reactants are of interest. For example, Zhang et al. described a continuous-flow synthesis of
11 Introduction
OME over alumina supported zirconia catalysts and over ion-exchange resins95, 96 and Burger
et al. patented a continuous process with Amberlyst 46 ion-exchange resin.97
Table 2.2: Overview of batch-mode OME synthesis procedures based on heterogeneous catalysis. The ratio of capping agentand formaldehyde source is given as mass ratio (wt.) or molar ratio (mol.). Maximum conversion (Xmax) is indicated withrespect to FA source if not otherwise indicated. Maximum selectivity (Smax) is lumped for a group of OME homologues asspecified in the reference. The reactant combination MeOH/FA corresponds to a methanolic formaldehyde solution.
cap.agent
(1)
FAsource
(2)
ratio(1):(2)
catalysttype
cat.loading/ wt%
T/ °C
t/ min
Xmax
/ %Smax
/ %ref
OME1 TRI 2.5 : 1(wt.)
ion-exchangeresins
7.5 90 30 89 OME3-8: 64.2 98
OME1 TRI 1:1(mol.)
ion-exchangeresins
ca. 10 100 480 - OME2-4 :22.3 99
OME1 TRI 2:1(wt.)
ion-exchangeresins
ca. 5 50/90
> 60 93 OME2-8: 51OME3-8: 27
66
OME1 TRI 1:1(mol.)
sulfonic acidfunctionalisedsilica
2 100 60 95.6 OME2-8: 61.8 100
OME1 TRI 2:1(mol.)
supported ionicliquids
4 105 60 92 OME3-8 : 52 101
OME1 TRI 3:1(mol.)
zeolites 0.3 25 60 94.5 OME3-5: 21.3 102
OME1 TRI 2 (wt.) zeolites 5 120 45 85.3 OME2-8: 88.5 103
OME1 TRI 3.3:1(wt.)
zeolites 0.5 70 250 ca. 95 OME3-5: ca. 43 104
OME1 TRI 1:1(mol.)
zeolites 5 120 1200 92.4 OME2-8: 90.6OME3-8: 60.3
105
OME1 TRI 2.5 : 1(wt.)
alumosilicates 7.5 105 120 92.6 OME2: 45.1OME3-8: 53.5
106
OME1 TRI 1:1(mol.)
alumosilicates 2 100 60 92.7 OME2-8: 56 107
OME1 TRI 1:1(mol.)
sulphated TiO2 1 80 60 89.5 OME3-8: 54.8 108
OME1 PF 3:1(wt.)
ion-exchangeresins
5 80 120 84.7 OME3-5: 36.6 58
OME1 PF 2:1(wt.)
ion-exchangeresins
- 90 360 - OME2-5: 41.2OME3-5: 22.1
109
OME1 PF 1.25:1(mol.)
ion-exchangeresins
5 90 120 77.5 OME3-6: 41.5 110
OME1 PF 2:1(mol.)
ion-exchangeresins + LiBrpromotor
ca. 10 100 1440 - OME2-4: 33.0 99
OME1 PF 3:1(mol.)
sulphated TiO2 3 80 50 ca. 85 OME3-5: ca. 22 111
Introduction 12
cap.agent
(1)
FAsource
(2)
ratio(1):(2)
catalysttype
cat.loading/ wt%
T/ °C
t/ min
Xmax
/ %Smax
/ %ref
MeOH TRI 2:1(mol.)
zeolites 5 120 600 100 OME3-8: 29.4 112
MeOH TRI 2:1(wt.)
Pd-modifiedH-ZSM-5
1 130 - 95.2MeOH
OME2-5: 62.9 113
MeOH TRI 2:1(mol.)
PVP-stabilisedheteropoly acids
2 140 240 95.4 OME2-5: 54.9 114
MeOH TRI 2:1(mol.)
graphene oxide 5 120 600 92.8 OME2-8:30.9 115
MeOH TRI 2:1(mol.)
H-MCM-22zeolite
5 120 600 39.8 OME2-8: 65.1OME3-8 : 39.4
105
MeOH TRI 2:1(wt.)
sulphatedFe2O3-SiO2
1.5 130 120 81.9 OME3-8: 23.3 116
MeOH FA various ion-exchangeresins
ca. 5 >100 39 OME1 :14.4 w%a
OME2: 10.3 wt%a
OME3: 6.7 wt%a
OME4 :4.0 wt%a
117
MeOH FA 0.67:1(wt.)
ion-exchangeresins
0.5 80 >180 44 OME1 :14.8 w%a
OME2: 10.4 wt%a
OME3: 5.9 wt%a
OME4 :4.0 wt%a
118
MeOH FA 0.67(wt.)
ion-exchangeresins andzeolites
1 40-120
> 20 - OME1 :15.8 w%a
OME2: 9.9 wt%a
OME3: 5.6 wt%a
OME4 :3.1 wt%a
68
MeOH FA 0.5:1 ion-exchangeresins
10 40-80 180 - - 119
DME TRI 4:1(mol.)
H-BEA zeolite 0.4 80 960 13.9DME
not indicated 73
a overall mass fraction at chemical equilibrium
2.3 Solid acid catalysis
Solid acids are widely applied in catalytic processes in the petrochemical industry and
chemical synthesis. Historically, solid acid catalysts have replaced liquid mineral acids in
various processes, owing to advantages, for example, in process engineering, handling,
separation and regeneration.120
Generally, solid acids catalysts are characterised by the presence of Brønsted (proton
donating) and/or Lewis acidic (electron pair accepting) groups. The acid groups can be located
at the surface and/or inside the solid. In case of supported acids, the acid sites are in the active
phase that is distributed on the internal and/or external surface of a support.
13 Introduction
In contrast to acids in solution, acid sites are not mobile in the reaction medium and their
properties depend on the local environment within the solid structure. Also, interactions of
molecules with the acid sites are influenced by factors such as surface adsorption, diffusion to
or accessibility of acid sites. It is then not surprising that the experimental methods to measure
acid properties of acids in solution and solid acids differ profoundly as described in
chapter 2.3.
Common examples of solid acids are alumina, amorphous and crystalline alumosilicates
(zeolites), functionalised metal oxides, ion-exchange resins, activated carbons, supported
mineral acids, and heteropolyacids.120 In this work, mainly zeolites and supported phosphoric
acid catalysts have been studied. These classes of catalysts will hence be described in more
detail in the following.
2.3.1 Zeolites121, 122
The term “zeolites” traditionally includes naturally occurring or synthetic crystalline
alumosilicates with structure-inherent porosity, which consist of a three-dimensional
framework of corner-connected tetrahedral primary building units (SiO4 and AlO4). The
excess charge related to the Al-containing tetrahedra is compensated by cations.123 A general
formula such as
⁄ ∙ ∙ ∙ (1)
is used in order to indicate the composition of the material. Similar materials including other
primary units, for example Al-P based aluminophosphates (ALPO), Si-Al-P based
silicoaluminophosphates (SAPO) based frameworks, and zeolitic materials with incorporated
germanium, titanium and other metals have been reported.123
The compensating cations in the zeolite structures are exchangeable. This is, for example,
exploited in the application of zeolites as ion-exchangers in detergents, which is also the
largest field of application.124 For use in acid catalysis, the cation is typically a proton. The
pores in the inorganic framework have a regular periodic arrangement and are of molecular
size. They can form one- to three-dimensional networks depending on the structure type. The
characteristics of zeolite porosity are of importance in applications as adsorbents as well as in
catalysis.
Introduction 14
The above described zeolite properties account for their use in a large range of applications,
for example as detergents, in agriculture, as adsorbents and pigments and in catalysis. In
catalysis, oil refining, the (petro)chemical industry and environmental catalysis are the most
important fields of application. Until today, a large variety of frameworks has been reported.
Out of the 248 listed framework types in 2018,125 only few are, however, of commercial
interest.
The acidic properties of zeolites are the basis for their use as catalysts in industrially relevant
acid-base reactions, such as isomerization, cracking, (de)alkylation, Friedel-Crafts reactions,
addition and elimination reactions as well as oligomerization reactions. Zeolites can contain
Brønsted and Lewis acid sites with a variable acid strength. Despite the very weak acid
strength, also silanol groups may play a role in zeolite reactivity. The concentration and
strength of the three types of acid sites depend on multiple factors, including structure type,
composition and treatment of the material.
The Brønsted acid site is the most common and well-studied type of acid sites in zeolites. It
occurs when a three-valent Al+ replaces a four-valent Si+ in the tetrahedral TO4-building unit
and when the charge is compensated by a proton. In this case, it is suggested that the proton is
present in form of a bridging hydroxyl group (see Figure 2.3 a). The bridging OH-groups are
commonly strong Brønsted acid sites. However, the strength of bridging hydroxyl groups is
influenced by the local environment. For example, acid sites at different positions within the
framework may differ in the degree of interaction with neighbouring atoms. Additionally, the
Al content has an impact on the acid strength. The more Al is located in close proximity of a
Brønsted acid site within the framework, the lower is the acid strength. This effect is most
prominent at high Al loading.
Figure 2.3: Schematic representations of a) a Brønsted acidic bridging hydroxyl group, b) a proposed form of a Lewis acidicextra-framework Al species and c) an isolated (terminal) silanol group in zeolites.
15 Introduction
Lewis acidity may arise from various sources. Firstly, charge-compensating metal ions
commonly represent weak Lewis acid sites. Secondly, so-called extra-framework aluminium
(EFAl) can form when Al is removed from the framework, commonly showing Lewis acidity.
The removal can occur during steaming, acid leaching and thermal or hydrothermal treatment.
However, the term EFAl groups various Al-containing species and the elucidation of their
chemical nature and their distribution is challenging. An AlO+ complex is exemplarily
depicted in Figure 2.3 b. Alternatively, AlxOyn+ complexes, uncharged Al2O3 particles and
AlO(OH) have been proposed to form.126 It is evident that the Lewis acidity of EFAl will
depend on which species are present. It is interesting to note that Lewis acidic EFAl species
interacting with Brønsted acid have been reported to increase the acid strength of the Brønsted
acid site.127
Silanol groups (Si-OH) are very weakly acidic and are not typically considered in zeolite acid
catalysis. However, in few cases such as the Beckmann rearrangement, silanol groups act as
active sites. Siliceous zeolitic materials such as Silicalite-1 are active in the industrially
relevant rearrangement of cyclohexanone oxime to caprolactam.128 Generally, silanol groups
can occur on the external surface of zeolite crystals, or in the bulk on framework defects. Also,
the Si-OH groups can be either isolated (Figure 2.3 c), vicinal, or in clusters. The latter is
argued to occur at a silicon vacancy and has been proposed to be the active site in Beckmann
rearrangement.128, 129
From the above description of acid sites in zeolites, it is evident that the acidity of zeolitic
materials is, except for Si-OH groups, determined by the Al content. According to the
Löwenstein-rule, there is a limit of Al content at a Si/Al ratio of 1:1 as AlO4 tetrahedra are not
stable when directly connected to each other.130 A short overview of methods available for
studying the nature, density, and strength of acid sites in zeolites and other solids is given in
chapter 2.3.3.
In the following, selected aspects of zeolite structural properties that are important in the
context of acid catalysis will be discussed. Information on further structure-related aspects
such as secondary and tertiary building units, nomenclature, classification of structure types
and others can be found in reference 122.
In zeolite catalysis, the highly ordered pore system is the most important structural feature that
governs various catalyst properties. The pore size and volume influences, for example, the
Introduction 16
surface area, sorption of guest molecules, the accessibility of reactants to active (acid) sites in
the inside of zeolite crystals, the stabilisation of transition states and intermediates, often
termed shape-selectivity, and deactivation tendency via pore blocking.
The porosity of idealised zeolite crystals is defined by the zeolite framework type. The latter
describes the connectivity of tetrahedral TO4 units and is classified by the International Zeolite
Association using three letter codes.125, 131 The framework type specifies the size of pore
openings and channels as well as the dimensionality of the pore network. Pore opening size is
typically indicated as number of TO4 units connected to a ring at the pore opening. It can be
classified according to ring size: 8-ring (small), 10-ring (medium) and 12-ring (large). For
elucidation and study of framework type, powder X-ray diffraction is a method of choice.
The textural properties of a real zeolite material are not only determined by framework type,
but chemical composition, defect density and presence of extra-framework species (cations,
water, organic compounds, adsorbed molecules, EFAl) have major impact on porosity and
surface area. It is therefore necessary to study the textural properties for individual zeolite
samples. For the investigation of zeolite textural properties, such as porosity and surface area,
gas physisorption is a well-established technique.
2.3.2 Supported liquid phase catalysts
A supported liquid phase (SLP) catalyst may be defined as a catalytically active material
dispersed in/on an inert (porous) solid that is dissolved or molten at reaction temperature.132,
133 Different systems have been described that involve molten salts as well as organic or
aqueous phases. When a supported salt has a melting point below 100 °C, the term supported
ionic liquid phase (SILP) is commonly used.
The first applied supported liquid phase catalyst was the silica-supported V2O5 alkali-
pyrosulphate catalyst for the oxidation of sulphur dioxide in sulphuric acid production. The
presence of a molten phase in the catalyst was, however, only elucidated three decades after its
introduction in 1914.133 Another prominent example is the Deacon catalyst, which is based on
supported CuCl2 with promotors, and which is used for the oxidation of hydrogen chloride and
for the oxidative chlorination of unsaturated hydrocarbons.132
While the two latter catalysts systems aim at oxidation and oxychlorination reactions, the so-
called solid phosphoric acid (SPA) catalyst is an industrially relevant SLP catalyst for acid-
catalysed reactions. As a supported phosphoric acid catalyst has been applied in this work, it
17 Introduction
will be described in more detail below. In more recent reports, the immobilization of
catalytically active metal organic complexes via dissolution in a supported ionic liquid (SILP)
or aqueous phase (SAP) has been described and applied to various reactions such as
hydroformylation.133
It is important to note that while the synthesis of SLP catalysts is often simple, the state of the
catalyst under reaction conditions may be complex. For example, the catalytically active
component may either be the molten salt (chlorides in Deacon catalyst) or the dispersed liquid
itself (H3PO4 in SPA catalyst) or it may be dissolved in a molten salt (V2O5 in alkali
pyrosulphate in the sulphuric acid catalyst and SILP catalysts) or in an aqueous phase (SAP
catalysts).
Phosphoric acid supported on a silica matrix, often naturally occurring Kieselgur, is a purely
Brønsted acidic catalyst that has been used as a solid acid catalyst since the 1930s.134 It is
commonly referred to as solid phosphoric acid (SPA). The main applications of SPA in
industrial processes are the oligomerisation of low molecular weight alkanes to form high
octane gasoline and the synthesis of ethylbenzene and cumene by alkylation of benzene with
ethylene or propylene, respectively. Furthermore, SPA have found application in hydration
reactions such propene to propanol transformation.133
Prepared by simple impregnation of ortho-phosphoric acid (H3PO4) on silica and subsequent
calcination, the final catalyst comprises many components. Firstly, condensed phosphoric acid
species such as pyro- and polyphosphoric acid can be present.133 Furthermore, various silicon
phosphate phases form upon calcination when silica is used as support.134 It is challenging to
determine the distribution of ortho-, pyro- and polyphosphoric acids under reaction conditions.
As the performance of the catalyst is strongly dependent on the concentration of water in the
reactant feed, is has, however, been argued that free ortho-phosphoric acid is the main active
species in oligomerisation and alkylation reactions.135
The main advantages of SPA are the low cost and high selectivity for Brønsted acid catalysed
reactions. Disadvantages include limited lifetime and the fact that the catalyst cannot be
regenerated.133 Although phosphoric acid has a very low vapour pressure,136 a possible loss of
active phase via leaching, and equipment corrosion must also be considered. Therefore, SPA
has been substituted by zeolite catalysts in some processes such as cumene synthesis. It is,
however, still in wide-spread industrial use.133, 137
Introduction 18
As described above, phosphoric acid is commonly supported on silica in industrial
applications. In scientific reports, also other supports, such as carbon (H3PO4/C)138 and
alumina (H3PO4/Al2O3)139 are reported. Another class of material, which is based on a
preparation route similar to H3PO4/C, are phosphorylated carbons. These materials are,
however, subjected to high-temperature treatment and subsequent washing, resulting in the
formation of C-P bonds and removal of free phosphoric acid.140 Phosphorylated carbons are
therefore not considered as SLP catalysts.
2.3.3 Characterisation methods126, 141
In general, four main aspects can be considered when studying solid acid catalysts and the
related reactivity. Firstly, the nature of acid sites including Brønsted and Lewis types is
important. Likewise, the strength of acid sites has an impact on catalyst activity. In case of
Brønsted acids, the strength relates to the readiness of proton transfer and can be expressed as
intrinsic or relative strength. Thirdly, the acid site concentration or density can be measured.
Finally, the impact of accessibility of active sites may not negligible for porous solid catalysts,
especially when bulky reactants or products are involved.
As supported liquid phase catalysts as well as conventional solid catalysts are used in this
work, it is of interest to briefly discuss the difference in acid characterisation for liquid and
solid acids.141, 142 This comparison also demonstrates, why the two main catalyst classes
studied in this work cannot be characterised with the same methods.
In proton donor-type (Brønsted) acids in aqueous solutions, acid sites are mobile. Their
strength can be related to the intrinsic acid strength of the H3O+ species whereas the acid
concentration is related to the acid dissociation constant Ka of the acidic molecule in solution.
The latter is often expressed in the logarithmic form, the pKa. Various methods for
determination of pKa in dilute aqueous solutions are known with some of the most established
being potentiometry, conductometry, and electrophoresis. In non-aqueous medium, for strong
acids or for concentrated solutions, a method relying on spectrophotometric measurement of
the dissociation degree of indicators according to works by Hammett is preferred. The latter
method is one of the few that has been applied to both liquid and solid acids. The concept of
acid strength is typically not applied to Lewis acids in solution. The Lewis acidic chemical
species are rather described according to their reactivity.
19 Introduction
While liquid or dissolved acids typically feature either Brønsted or Lewis acidity, both acid
types can be present within a solid material. They may even interact, resulting in changed acid
strength. This renders a careful analysis of the nature of the acid site present in the catalyst
necessary. In Table 2.3, an overview of characterisation methods for solid acids is given. As
zeolites are of importance to this work and as the majority of literature on acid site
characterisation is focussed on zeolites, the table includes notes on the applicability of
methods to zeolite materials. An additional method not included in Table 2.3 is model
catalytic reactions.141
Table 2.3: Overview over methods for characterization of solid acids with a focus on zeolite analysis.126, 141
nature of acid sites(Brønsted / Lewis)
number/densityof acids sites
strength (distribution)of acid sites
computationalmethods Brønsted acids ---
computed deprotonationenergy, zeolites: topologicaldensity of Al tetrahedra
Hammettindicators &butylaminetitration
Brønsted acids
butylamine titration(constraint:accessibility of bulkacid sites)
acid strength via colourchange of indicators uponprotonation(constraint: only strength ofstrongest acid site is measured,properties of indicators may beinfluenced by surfaceadsorption143)
NH3-TPD non-selective via sum of desorbedNH3
via temperature of desorption(constraint: only approximatemeasure, preferably only usedfor ranking of similar samples)
1H MASNMR144
different Brønsted acidsites via chemical shiftof -OH groups, differentLewis acid sites viachemical shift of adsorbedprobe molecules
quantification viacomparison with astandard
Brønsted acids via chemicalshifts induced by probemolecules, not viable forLewis acid sites
MAS NMRwith othernuclei144
27Al MAS NMR:coordination environmentvia Al chemical shift,assignment to framework(mainly Brønsted) andextra-framework (mainlyLewis) sites in zeolites
---
Brønsted acids via chemicalshifts induced by probemolecules, (e.g. 31P MASNMR of trimethyl-phosphine),not viable for Lewis acid sites
Introduction 20
nature of acid sites(Brønsted / Lewis)
number/densityof acids sites
strength (distribution)of acid sites
FTIRwithout probemolecules
different Brønsted acidsites via characteristicwavenumber of -OH groupstretching vibration
--- ---
FTIR withbasic probemolecule,e.g. pyridine
different Brønsted andLewis acid sites
Only in transmissionmode, via Lambert-Beer law (constraint:availability ofextinctioncoefficient, acid siteaccessibility)
band shift and temperature ofdesorption of probe molecule
Microcalori-metricmeasurements
non-selectivevia amount of basicprobe necessary toneutralise acid sites
via measurement ofdifferential heat of adsorptionof probe molecule (constraint:influenced by van der Waalsinteractions145)
2.4 Methanol dehydrogenation
In a production process of OME via methanol and formaldehyde as studied in this work, the
reactants can be supplied via partial methanol dehydrogenation. In order to combine methanol
dehydrogenation with OME synthesis, it is necessary to consider the characteristics and
available catalyst systems for this reaction.
2.4.1 Oxidative vs. non-oxidative route
For the catalytic transformation of methanol to formaldehyde, there are two approaches:
oxidative and non-oxidative dehydrogenation. The former is employed industrially and is the
main production pathway of formaldehyde. It is carried out in large scale owing to the
importance of formaldehyde as an intermediate for production of resins, pesticides,
disinfectants, dyes, preservatives, explosives, paper and others.65
It is an exothermic reaction (ΔHR = -159 kJ/mol)65 that follows the overall reaction presented
in equation (2-1).
+ 0.5 ⎯⎯⎯ + (2-1)
Two different process routes can be distinguished, mainly differing in catalysts used and in
reaction conditions. On the one hand, a methanol-rich feed stream can be converted over silver
21 Introduction
catalysts at 600 - 720 °C. Water vapour is fed in order to maintain the catalyst activity. For
this catalyst system, a two-step reaction via methanol dehydrogenation and subsequent
oxidation of hydrogen to water is reported. Hence, this route is also referred to as
oxydehydrogenation. On the other hand, a catalyst based on molybdenum, vanadium and iron
oxides can be used for methanol conversion in excess oxygen at 300 - 450 °C. In this case, the
mechanism relies on a single oxidation step.146
The non-oxidative dehydrogenation of methanol (see equation (2-2)) is currently not used in
large-scale industrial processes. However, this reaction has been studied with the intent to
circumvent formaldehyde – water separation for applications in which anhydrous
formaldehyde is required, for example production of polyoxymethylene thermoplastics.147
Another advantage is that hydrogen is a more valuable by-product than water.
⎯⎯⎯ + (2-2)
As it is an endothermic reaction (ΔHR = 84 kJ/mol)65 it needs to be carried out at elevated
temperatures. Thermodynamically, the formation of formaldehyde is favoured at temperature
above 475 °C.147 In this temperature range, the decomposition of formaldehyde to carbon
monoxide and hydrogen is, however, a prominent side reaction, which occurs even without
catalyst.147 Therefore, short residence times in the reactor are crucial.
2.4.2 Catalysts
In this work, the non-oxidative approach to methanol transformation was applied. Therefore,
the following short overview over the most relevant catalyst systems is limited to non-
oxidative methanol dehydrogenation. It is based on the comprehensive review by Usachev et
al.148
A range of catalyst systems for non-oxidative methanol dehydrogenation is described in
academic publications.147-149 Typical highly active (de)hydrogenation catalysts containing, for
example, platinum or iron150 are not among the catalysts suitable for MeOH dehydrogenation
due to an excess activity in formaldehyde decomposition to CO and H2. Rather, catalytic
materials with moderate (de)hydrogenation activity such as silver, copper and zinc dominate.
Additionally, catalysts containing sodium ions are reported to be active.148
The majority of studies on non-oxidative methanol dehydrogenation are based on zinc in the
form of molten metal, zinc alloys, zinc oxide and Zn ion-exchanged catalysts. A large range of
Introduction 22
supports and co-catalysts including oxides of silicon, lanthanum, iron, indium, cerium,
tellurium, chromium and sodium have been reported. Silica supported ZnO catalysts and Zn
exchanged zeolite show the highest formaldehyde yields. It should be noted that elemental
zinc or Zn2+ reduced under reaction conditions can be leached out of the reactor in the form of
Zn vapour.148 A range of studies describe copper catalysts for non-oxidative methanol
dehydrogenation. While pristine copper deactivates quickly, increased stability was claimed
for various catalytic systems based on copper alloys or supported copper (II) oxide. The best
performance was reported for CuZnS, CuZnSe and CuO-Cu3(PO4)2/SiO2 catalysts.148 In the
class of silver based catalysts, pristine Ag and alloys containing Cu, Zn and/or Te are
mentioned. In contrast to commercial methanol oxidation catalysts based on molybdenum and
iron oxides, which are not active in non-oxidative methanol dehydrogenation, silver is active
in both dehydrogenation pathways. As mentioned above, the oxydehydrogenation of methanol
over silver proceeds via initial dehydrogenation of methanol and subsequent oxidation of
hydrogen. It is interesting to note that under non-oxidative conditions, silver catalysts need to
be pre-treated and regularly reactivated with oxygen, suggesting that also in this case, an
oxydehydrogenation mechanism may be involved. High initial formaldehyde yields and fast
deactivation is commonly described.148
The presence of transition metals is not mandatory to yield an active catalyst for the formation
of anhydrous formaldehyde. Sodium exchanged zeolites were patented for methanol
dehydrogenation to formaldehyde. Also, reports on sodium metal catalysts are available.
Interestingly, simple salts containing sodium ions achieve comparable performance to the
above described transition metal based catalyst classes. Among the studied simple sodium
salts, including carbonate, tetraborate, phosphate, molybdate, sulphate and aluminate anions,
the highest formaldehyde yields are obtained over sodium carbonate.148
23 Motivation and research objectives
3 Motivation and research objectives
Synthetic fuels based on oxymethylene ethers have the potential to play a key role in
decreasing road transport emissions and in building a fuel infrastructure independent of fossil
resources. As OME synthesis remains the main challenge for its commercialisation as an
additive or fuel for compression-ignition engines, it is of interest to study alternative
production pathways.
In current industrial synthesis routes,118 the major drawback is the large number of process
steps, including five main steps: (1) formation of MeOH, (2) production of aqueous
formaldehyde, (3) synthesis of the intermediate OME1, (4) synthesis of intermediate trioxane
or paraformaldehyde and (5) OMEn formation. The latter three process steps are based on
liquid-phase processes. Another disadvantage is the need for a highly energy demanding
separation of the intermediates.
In perspective of a future large-scale production of OME for supplying large enough quantities
to use OME as a fuel, gas-phase technology has the advantage of easier scalability, improved
process integration and easy implementation of continuous processes. Potentially, OME could
be produced in a complete continuous gas-phase process in only three process steps starting
from CO or CO2 and H2 (syngas) including (1) synthesis of methanol, (2) subsequent partial
dehydrogenation to formaldehyde to yield the FA/MeOH reactant mixture, and (3) formation
of OMEn (see Figure 3.1).
Figure 3.1: Schematic representation of the three steps involved in the targeted gas-phase process.
The transfer of the last process step, namely the formation of OME from methanol and
formaldehyde, from liquid to gas-phase is one of the two main objectives of this work. The
second focus is the in-depth study of solid acid catalysts for gas-phase OME synthesis.
For these aims, it was targeted to build a versatile catalytic test set-up and to perform
preliminary studies on reaction conditions and on solid acid catalyst classes. The gained
knowledge was envisaged to be applied in the in-depth study of structure-activity relations of
Motivation and research objectives 24
active catalysts. Finally, the gas-phase synthesis of OME from methanol without separation of
intermediates was aimed to be implemented as a proof of concept for the viability of the above
described complete gas-phase OME synthesis.
25 Description of test set-up
4 Description of test set-up
The construction of a flow set-up was a prerequisite to perform the targeted catalytic studies
described above. Design, assembly, implementation, and calibration of the set-up were an
integral part of the project and will therefore be described in this chapter. The set-up was
designed to allow for flexibility to explore reaction parameters in a large range, e.g.
temperature, pressure, reactant concentration, and residence time. Additionally, an emphasis
was laid on ensuring safe handling of the pressurized equipment and of hazardous and
flammable reagents involved.
The set-up built is a continuous flow set-up with a fixed-bed reactor. It allows performing
reactions at up to 400 °C and up to 25 bars.
4.1 Concept
The underlying concept is depicted in Figure 4.1. The reactants are supplied in liquid form and
transported to a heated evaporator unit by a pump. Inside the evaporator, the evaporated
components are mixed with a flow of inert gas. The latter is supplied from a gas bottle and is
adjusted using a pressure regulator and mass flow controller. The flow of diluted reactants can
be passed through the reactor containing the catalyst to be tested. Alternatively, the reactor can
be bypassed in order to analyse the reactant stream directly. The pressure inside the system is
controlled by a back pressure regulator placed at the downstream end of the pressurized zone.
At the outlet of the set-up, an online gas chromatograph for qualitative and quantitative
analysis of the gas stream is located.
Figure 4.1: Conceptual schematic representation of the test set-up.
Description of test set-up 26
4.2 Technical implementation
A more detailed representation of the set-up is given in Figure 4.2 and Table 4.1. It includes
information on technical instrumentation, piping and gas supply.
Figure 4.2: Detailed schematic representation of the test set-up. The main pathway of carrier gas and reactants is marked inbold lines. The heated zone is marked in orange. Detailed information is listed in Table 4.1.
Table 4.1: Description of set-up components as displayed in Figure 4.2.
1 supply of carrier gas 15 line for reactor purge andpressurization 29 pressure transducer with elevated
temperature resistance2 supply of helium 16 line for reactant solution outgassing 30 additional reactor (R1) and circular oven
3 supply of synthetic air 17 venting system 31 reactor (R2) and circular oven
4 supply of nitrogen 18 proportional relief valve 32 reactor bypass line
5 supply of hydrogen 19 line towards vent 33 line for reactor pressure release and purge
6 pressure reducers 20 pressure transducer 34 adjustable back pressure regulator
7 particle filter 21 reservoir of reactants (FA/MeOH) 35 line towards gas chromatograph
8 mass flow controllers 22 HPLC pump 36 gas chromatograph bypass, towards vent
9 magnetic valves 23 ball valve 37 condensation trap
10 check valve 24 reservoir for reactant waste frompurge 38 online gas chromatograph
11 bypass line for fastsystem pressurization 25 capillary towards evaporator 39 gas-washing bottle filled with water
12 ball valve 26 start of elevated temperature zone 40 gas-washing bottle with Na2SO3 solution
13 needle valve 27 evaporator heated by circular furnace
14 bypass line for fastreactor pressurization 28 high pressure ball valves
27 Description of test set-up
For the operation of any catalytic test set-up, the control of process parameters is essential.
This includes supply of gases and liquid reactants, regulation of pressure and gas flows as well
as heat control. The implementation is briefly described in the following sections.
4.2.1 Gas and pressure control
In the OME synthesis set-up, a premixed gas containing 5% methane in nitrogen is used as a
carrier gas (Figure 4.2: 1). Both components are inert in the studied reaction. While nitrogen is
employed for dilution, methane is added as an internal standard for GC analysis. It is supplied
in a high pressure gas cylinder (up to 200 bars) and is calibrated by the manufacturer. The
carrier gas is supplied to the reactor either via the main pathway highlighted in Figure 4.2 or
via several by-pass lines (Figure 4.2: 11,14,15). Additional gases such as helium, synthetic air,
nitrogen and helium (Figure 4.2: 2-5) are connected to the gas chromatograph. Helium is
additionally used for outgassing of the reactant solution (Figure 4.2: 16).
The gas flows into the system are regulated by mass flow controllers (MFC), which are
operated remotely via LabView software (Figure 4.2: 8). All MFCs have a flow range of up to
1 L/min (STP). The MFCs require a pressure gradient of approximately 10 bars between the
upstream and downstream outlet. The respective upstream pressure is adjusted by a pressure
reducer (Figure 4.2: 6). The downstream pressure in the system is set by the adjustable back
pressure regulator at the outlet of the set-up (Figure 4.2: 33). When the MFCs were calibrated
using a volumetric primary flow calibrator device, the same pressure gradient was applied. All
MFCs are protected by magnetic ball valves that separate the MFCs from the main system
when no reaction is running (Figure 4.2: 9). In the main feed line for the reactor, the MFC is
additionally equipped with a particle filter and a check valve (Figure 4.2: 7,10). The latter
allows flow only in the downstream direction and prevents pressure changes in the system to
affect the MFC.
The pressure in the system can be read from two pressure transducers, which are placed at the
inlet of the system (Figure 4.2: 20) and at the inlet of the reactor (Figure 4.2: 29), respectively.
4.2.2 Evaporator unit
The reactant solution contains approximately 60% FA, 38% MeOH and 2% H2O and is
obtained by dissolving paraformaldehyde in methanol via refluxing (see chapter 11.6.1). It is
supplied in a reservoir and outgassed with a flow of helium prior to use (Figure 4.2: 16,21).
Description of test set-up 28
The liquid is transported to the evaporator unit using a HPLC piston pump (Figure 4.2: 22).
The pump achieves flows as low as 2 μL/min. The reactants methanol and formaldehyde are
compatible with the provided pump. Other components such as oxymethylene ethers,
however, can only be pumped for short periods due to a limited chemical resistance of the
sealing materials.
While all other tubing of the set-up has dimensions of 6 mm outer diameter, the liquid feed
enters the evaporator via a capillary with 1.6 mm (1/16 inch) outer diameter (Figure 4.2: 25).
The thin capillary facilitates a constant flow of liquid into the evaporator even at very low
flow rates. It ends inside the heated zone of the evaporator, where the liquid evaporates in a
stream of carrier gas (Figure 4.2: 27). The evaporator volume is filled with inert granular
silicon carbide in order to improve evaporation and mixing with the inert gas by providing
high surface area.
4.2.3 Heating
All tubes downstream of the evaporator are heated to 170 °C in order to avoid polymerization
of formaldehyde and condensation of methanol and reaction products. The main components
of the set-up, such as evaporator, reactor and back pressure regulator, are equipped with
circular ovens. The connecting tubes are tightly wrapped with heating tape. The heated
components are furthermore wrapped in glass wool mats and tape as well as aluminium foil
for insulation. The ovens and heating tapes are regulated by individual in-house built
temperature controller units. The directing temperature input is supplied by thermocouples
placed closely to the heated components.
4.2.4 Reactor
The reactor is a flow reactor composed of a steel tube with an outer diameter of 10 mm and an
inner diameter of 5.8 mm (Figure 4.2:31 and Figure 4.3). It is equipped with an internal grid
that holds the catalyst bed in place. A thermocouple placed inside the catalyst bed permits to
measure the local temperature. Plugs of quartz wool placed at the inlet and outlet of the reactor
prevent contamination of connecting tubes with catalyst particles.
The catalyst bed is comprised of catalyst pellets (300-400 μm size range) diluted with inert
silicon carbide (46 grit) in a mass ratio of catalyst to SiC of 1:6. For catalyst activation prior to
reaction, the reactor can be purged and pressurized with inert gas (Figure 4.2:15 and 32).
29 Description of test set-up
Figure 4.3: Schematic representation of the reactor R2 for OME synthesis. View is turned from vertical to horizontal
orientation.
4.3 Product analysis
In addition to process control, the reliable analysis of feed as well as product composition is a
key prerequisite for catalytic testing.
In the constructed set-up, the analysis is based on gas-chromatography (GC). The GC device is
placed at the outlet of the set-up. It is equipped with a six-way valve for online sampling, a
polyethylene glycol based polar capillary column and two detectors connected in series, a
flame ionization detector (FID), and a thermal conductivity detector (TDC). For its operation,
various gases are supplied via the general laboratory gas system. While helium is used as the
carrier gas, synthetic air and hydrogen are required to sustain the hydrogen flame of the FID.
Nitrogen gas is connected to the pneumatic actuators of the 6-way sampling valve.
Prior to running a reaction, the feed concentration can be monitored via GC by setting the
respective valves in the set-up (Figure 4.2:28,32) to the bypass position. To start the reaction
and for product analysis, the valves are switched towards the reactor.
For quantification via GC, the retention times and response factors of the analytes need to be
determined prior to analysis. A range of compounds was available as pure substances, such as
methanol, methyl formate, trioxane, formic acid OME1, OME3 and OME4. This allowed
simple determination of retention times and response factors via injection of liquid aliquots of
pure components or prepared mixtures containing 1-butanol as an internal standard. In case of
DME, a calibration gas mixture was employed. For formaldehyde, the retention time was
determined via headspace sampling from paraformaldehyde heated at 100 °C.
Description of test set-up 30
Other OMEn and the hemiacetal of methanol and formaldehyde (hemiformal, HF) were
however not available as pure substances. Hence, their retention times were identified from a
reference liquid-phase OME synthesis. Trioxane and OME1 were reacted in an autoclave over
an acidic ion-exchange resin (see chapter 11.5). The product mixture was then analysed via
GC coupled with mass spectrometry (GC-MS). Response factors of OME2 and OME>4 were
extrapolated from the data obtained with pure OME1, OME3 and OME4 according to a method
specified in literature.117
In the test set-up, methane is used as an internal standard. Hence, the reference of response
factors was converted from 1-butanol to methane. For this purpose, the response factors of
MeOH, OME1 and OME3 with respect to methane were determined by evaporation of a
calibrated liquid feed. As the ratios of the response factors in the gas-phase were in agreement
with ratios determined from liquid injections, the other response factors were recalculated
accordingly without further experimental determination.
Similarly, the response factor of formaldehyde was determined by evaporation and analysis of
a calibrated liquid feed of a methanolic formaldehyde solution (see chapter 11.6.1). The
composition of the latter was identified via iodometry and Karl-Fischer titration (see chapter
11.6.2 and 11.6.3). It is important to note that the quantitative evaluation of hemiformal was
not feasible. On the basis of the marginal amount detected, the hemiformal content was
neglected, resulting in a minor systematic undervaluation of reactant concentrations. This is,
however, not expected to have a significant impact on catalytic data.
4.4 Safety features
In the test set-up, a range of chemicals with hazardous properties is employed, such as
formaldehyde (toxic, corrosive, irritant and is presumed to be carcinogenic) and methanol
(flammable and toxic). This necessitates rigorous safety precautions. OME are rated to be non-
toxic.18
In the context of process control, several safety features are included in the set-up design.
Firstly, a proportional relief valve is installed in order to release pressure from the system if a
threshold value is reached (ca. 40 bars, Figure 4.2:18). The heating units for the main
components, such as evaporator, reactor and back pressure regulator, are connected to in-
house built security shut-off units with an adjustable temperature threshold. In addition to the
general venting of the laboratory compartment where the set-up is installed, a vent is installed
31 Description of test set-up
above the set-up (Figure 4.2:17). It is connected to the central exhaust system of the
laboratory. In order to achieve a bottom-to-top venting, transparent polymeric curtains cover
the front and sides of the set-up. The curtains can be moved aside for operation and
maintenance of the set-up. Before entering the general venting system, the set-up exhaust
gases are passed through two gas wash bottles filled with water and aqueous sodium sulphite
solution in order to absorb formaldehyde and other organic components (Figure 4.2: 39,40).
The time spent inside the laboratory compartment is minimised through computer based
remote access to key process parameters. Gas flow rates are adjusted via a LabView software
panel. Also temperature and pressure can be monitored remotely.
For the prevention of hazards related to formaldehyde, additional personal protective
equipment is provided. A handheld formaldehyde meter based on electrochemical sensing is
allocated at the entry of the laboratory compartment for regular testing of formaldehyde
concentration. An acoustic alarm signal turns on at >0.3 ppm of formaldehyde in the air. The
use of a non-stationary detector allows localising a formaldehyde source, for example a leak, if
necessary. A full-face gas filtration mask is also provided at the entry of the compartment. It is
fitted with a filter targeting a range of organic substances including formaldehyde and
methanol.
4.5 Extensions for combined process
For the implementation of OME synthesis from methanol, a second reactor suited for
methanol dehydrogenation was introduced to the set-up.
Figure 4.4: Schematic representation of the reactor R1 for methanol dehydrogenation. Gas flow is directed from left to right
side.
The reactor is a flow reactor composed of a tube with an outer diameter of 10 mm. It is fitted
with a quartz tube with an inner diameter of 5 mm (Figure 4.2:30 and Figure 4.4). The quartz
Description of test set-up 32
liner is included in order to avoid potential blind reactions induced from components of the
steel reactor walls (1.4571 type steel). The catalyst bed is held in place by quartz wool plugs.
A thermocouple is placed closely to the catalyst bed. The catalyst bed is comprised of catalyst
pellets diluted with inert silicon carbide. Similar to reactor R2, the reactor can be purged and
pressurized with inert gas prior to reaction (Figure 4.2:15 and 32). It holds pressure up to
20 bars. The reactor is heated in a circular oven unit that has a temperature rating of 650 °C.
The unit was designed and built in the fine mechanics workshop of the institute.
In contrast to OME synthesis from formaldehyde and methanol, methane is a potential by-
product and is hence not a suitable internal standard for GC quantification. The experiments
were carried out with pure N2 as carrier gas. Relative response factors of reactants and
products were calculated and used for data evaluation.
33 Screening of reaction conditions
5 Screening of reaction conditions
Prior to systematic investigations of catalyst performance and structure-activity relations
described in chapters 6, 7 and 8, a range of suitable reaction conditions was determined using
an exemplary industrial catalyst. An H-form mordenite zeolite with a SiO2-to-Al2O3 ratio of
40, denoted as H-MOR-40, was used for all experiments described in this section if not
specified otherwise. In the following, the effect of various reaction parameters on the
conversion and selectivity will be presented and discussed. The studied parameters include
reaction temperature, total pressure and partial pressure of reactants, reactant ratio, water
content, pellet size and catalyst activation protocol. In this context, the reproducibility of the
test reaction was also assessed.
5.1 Temperature
The temperature dependence of catalyst activity was studied in the range of 130 – 270 °C
(Figure 5.1, left). Firstly, a test run with increasing temperature steps from 170 to 270 °C was
conducted. Upon return to the initial temperature level at 170 °C, the conversion and
selectivity had only changed to a minor extent. This indicates that (de)activation of the catalyst
did not occur on the time scale of the experiment and that the trends in catalyst performance
can be attributed to a temperature effect. Due to the superior performance at 170 °C, a data
point at 130 °C was collected in a supplementary test run.
Figure 5.1: Conversion and selectivity of H-MOR-40 (left) and Silicalite-1 (right) as a function of temperature. Reactionconditions: 0.5 g catalyst pellets in 3 g SiC 10 bar, 100 ml/min inert gas flow, 14 μl/min FA/MeOH mixture.
Screening of reaction conditions 34
Under the studied conditions, varying amounts of the products OME1 and OME2 as well as by-
products methyl formate (MeFO) and dimethyl ether (DME) were observed. A pronounced
influence of temperature on both conversion and selectivity is evident. OME selectivity
decreased from 72% at 130 °C to 3% at 220 °C. No OME is detected at 270 °C using
H-MOR-40.
When discussing the observed decrease in selectivity towards OME at increasing temperature,
two aspects need to be taken into account: Firstly, the intrinsic thermodynamics of OME
synthesis and secondly, the competing side reactions. The latter will be described below.
Computational studies of the thermodynamics of OME formation demonstrate that the
equilibrium reaction between any set of reactants and OME is strongly shifted towards the
reactant side with increasing temperature.151 The latter effect can be examined independently
of by-product formation when Silicalite-1 catalyst is employed. It is a very weakly acidic
siliceous zeolite material that was identified to be active in OME synthesis during
investigations described in chapter 7. Silanol groups, which are the active species in
Silicalite-1, do not favour DME or MeFO formation. Over Silicalite-1, a steady decrease in
conversion upon increase in reaction temperature occurs. OME selectivity is not significantly
influenced. This emphasises that in case of H-MOR-40, the catalyst activity towards by-
products determines the product distribution. In this context, it is of interest to discuss by-
product formation and assess the reversibility of the competing reactions.
While MeFO is the major by-product in the lower measured temperature range, DME
formation is favoured with increasing reaction temperature. DME is formed via acid catalysed
dehydration of methanol (see equation (5-1)). DME formation is not an equilibrium reaction is
hence showing an increase in reaction rate upon increasing temperature. This is in line with
reports of methanol dehydration over zeolites or alumina having an increasing reaction rate in
the range of up to approx. 300 °C.152, 153
2 ⎯⎯ + (5-1)
For the formation of methyl formate, two reaction pathways need to be considered. Firstly, a
Cannizzaro-type reaction (equation (5-2)) and a subsequent esterification (equation (5-3)) can
occur.154
2 + ⎯⎯ + (5-2)
+ ⎯ (5-3)
35 Screening of reaction conditions
Under the studied reaction conditions, formic acid was not detected irrespective of catalysts
and product distribution. Previously, the retention time of formic acid in the gas
chromatograph was determined. A response factor was not established for formic acid, for
which reason the formation of minor amount of formic acid cannot be ruled out. However, the
Cannizzaro reaction typically requires strong bases such as sodium hydroxide.154
It therefore appears more likely that the formation of methyl formate proceeds via the second
possible pathway, namely the Tishchenko reaction. It is a one-step disproportionation-
dimerization reaction (equation (5-4)).
2 ⎯ (5-4)
The Tishchenko transformation of aldehydes is a well-established reaction in organic
synthesis. It is commonly performed using aluminium alkoxide catalysts in solution and
proceeds via a catalyst-coordinated hemiacetal transition state and a hydride transfer reaction
step.155, 156 While methyl formate is mentioned to be a potential by-product in OME liquid
phase synthesis, the formation mechanism is seldom discussed. However, some authors
attributed it to the Tishchenko reaction.66 There are only few reports of gas-phase Tishchenko
reaction with formaldehyde, in which mainly binary oxides have been employed. These
studies emphasise the importance of the presence of both acidic and basic sites in the
catalyst.157 Interestingly, in the base catalysed gas-phase aldol condensation of the
formaldehyde homologue propanal over HY zeolites, the Tishchenko reaction was likewise
reported to occur as a side reaction.158 In summary, it may be assumed that the formation of
methyl formate also proceeds via Tishchenko reaction in the case of zeolite H-MOR-40.
Exemplarily, the reversibility of methyl formate formation over H-MOR-40 was studied (see
Figure 5.2). At 130 °C, no conversion occurred upon exposure of a flow of MeFO to the
zeolite catalyst indicating the irreversibility of the reaction. It could furthermore be confirmed
that the formation of OME1 in the gas-phase is reversible. A feed of OME1 and water was
transformed into a mixture of reactants FA and MeOH and minor amounts of side products
MeFO and DME as well as OME2. The results highlight that the activity of a catalyst towards
the irreversible formation of side products has a major impact on the product distribution as
indicated above.
Screening of reaction conditions 36
Figure 5.2: Reversibility test for methyl formate (upper left) and OME1 (upper right) formation and respective reactionscheme (bottom). The dashed line indicates the switch from bypass to reactor. Reaction conditions: 130 °C, 10 bar, 0.5 gH-MOR-40, 100 mL/min inert gas flow, 28 μL/min feed of methyl formate or OME1 mixed with ca. 5% H2O. H2O is detectedbut not quantified.
In terms of the preliminary screening of suitable reaction conditions, it was necessary to make
a compromise between the favourable impact of a low reaction temperature and the required
temperature to keep all components in the gas-phase. The latter was estimated by taking into
account the saturation vapour pressure of reactants and potential products159, 160 as well as the
maximal expected partial pressures of the components in the test set-up. The temperature
130 °C was chosen and adopted for all further test runs.
5.2 Pressure
According to Le Chatelier’s principle, an equilibrium reaction that features a change in the
number of moles of its components will be affected by a change in reaction pressure. This
feature is valid for the initial hemiformal formation and for the chain-growth steps in OME
formation (see chapter 2.2.2 , Figure 2.2). When studying the pressure dependence of a
catalytic reaction, both the total pressure and the reactant partial pressure can be varied. To
test the sensitivity of the reaction to total pressure the reaction was performed at 10 and 20
bars while the reactant partial pressure was held constant. In both cases, no change in catalyst
37 Screening of reaction conditions
performance was observed. Tests at atmospheric pressure could not be evaluated due to
unsatisfactory carbon balance.
In contrast to total pressure, the partial pressure of both reactants has an impact on the final
product distribution (see Figure 5.3). Holding the reactant ratio constant, the reactant partial
pressure was increased in two steps. It resulted in an increase of OME1-3 selectivity. This
observation can be applied in further reaction condition optimisation. It should, however, be
kept in mind that in a gas-phase process, the partial pressure is restricted by the saturation
pressure of the components at which they will condense.
Figure 5.3: Conversion and selectivity of H-MOR-40 as a function of total (FA+MeOH) reactant partial pressure (left) and ofreactant ratio (right). Reaction conditions: 0.5 g catalyst pellets in 3 g SiC, 10 bar, 100 ml/min inert gas flow. Left: FA/MeOHfeed of 14, 30 or 45 μL/min with reactant ratio of 3:2. Right: 1.52 bar reactant partial pressure, 30 μL/min flow of reactantsolution with varying composition.
5.3 Reactant ratio
The product distribution at three different weight-based reactant ratios (3:2, 1:1 and 2:3
FA/MeOH) was obtained by successive addition of methanol to the reactant mixture. With
decreasing formaldehyde partial pressure, less OME chain growth occurs. At the same time,
the reactant conversion increases. For synthesis of OME>1 homologues, a high FA/MeOH is
favourable. In this work, the reactant solution was prepared by dissolution of
paraformaldehyde in methanol. The solubility of formaldehyde in methanol limits the
FA/MeOH ratio to 3:2.
Screening of reaction conditions 38
5.4 Water content
As described in chapter 2.2.2, the presence of water shifts the reaction equilibrium and hence
is expected to have an adverse effect on OME yield. When OME is synthesised according to
the so-called aqueous route from methanol and formaldehyde as starting materials, the
stoichiometric formation of water as a by-product cannot be circumvented.
For the catalytic tests described in the following chapters, it was of interest to assess the
impact of the water content of the reactant feed. In the test set-up, formaldehyde and methanol
are introduced via evaporation of a solution containing ca. 60 wt% FA, 37-38 wt% MeOH and
2-3 wt% H2O. The latter is prepared by dissolution of paraformaldehyde in methanol and the
water content is related to the end-groups of the paraformaldehyde polymers.
The impact of water addition was tested at 3.3, 17.7 and 22.8 wt% H2O. There was neither an
effect on conversion nor on product distribution (see Appendix, Figure 12.1). The results do
not allow extrapolating to lower water contents. A stronger correlation of initial catalyst
performance to water content may arise in this regime. Nevertheless, the reactant solution
obtained from paraformaldehyde dissolution with 2-3 wt% water content was found to be
suitable for the purpose of this work.
5.5 Pellet Size
It is important to verify that the catalyst performance is independent of pellet size for the
chosen reaction conditions in order to demonstrate the absence of mass transfer limitations.161
The latter include macroscopic effects such as channel formation inside the catalyst bed and
effects on the microscopic scale as for example diffusion limitations into the catalyst grain.
For this purpose, the catalyst activity of H-MOR-40 in two different pellet sieve fractions
(100 – 200 μm and 300 – 400 μm) was compared. There was only a marginal difference in
catalyst performance which may be attributed to the limits of reproducibility of the test set-up.
For further testing, the pellet size range of 300 – 400 μm was chosen for all powdered
catalysts.
5.6 Catalyst activation protocol
To study the impact of the in-situ catalyst activation procedure performed inside the test set-
up, two different protocols were compared. Interestingly, a thermal treatment at 300 °C for 2h
on the one hand and the heating of the catalyst at the reaction temperature 130 °C for 1h on the
39 Screening of reaction conditions
other hand yielded the same catalyst performance. For the sake of time efficient catalyst
screening and testing, the milder treatment at 130 °C was adapted.
5.7 Reproducibility
The reproducibility of catalytic tests was evaluated by 5-fold repetition of a test run with
following reaction conditions: 10 bar, 130 °C, 0.5 g H-MOR-40, 100 mL/min inert gas flow,
14 μL/min FA/MeOH solution feed (see Figure 12.2). The deviation of the arithmetic mean of
obtained conversion and selectivity results was below 3%.
Preliminary catalyst screening 40
6 Preliminary catalyst screening
In order to assess the potential of different classes of conventional solid acid catalysts for gas-
phase OME formation, representatives of proton form zeolites (H-MOR-40, H-FAU-5),
functionalised metal oxides (sulphated and tungstated zirconia, SO4-ZrO2 and WO3-ZrO2),
supported heteropoly acids (silicotungstic acid supported on alumina, HPA-Al2O3) and ion-
exchange resins (Amberlyst 36) were studied in the first stages of this work. In the group of
ion-exchange resins, Amberlyst 36 was chosen owing to its improved thermal stability up to
150 °C as specified by the supplier. Further information about the catalysts is supplied in
chapters 11.1.3 and 11.2.1.
Figure 6.1: Initial selectivity and conversion of solid acid catalysts determined in the interval of 40 - 70 min. reaction time.Residual activity measured without catalyst. Reaction conditions: 10 bar, 130 °C, 0.5 g of catalyst, 100 mL/min inert gas flow,14 μL/min FA/MeOH solution feed. WHSVFA: 1.1 g(FA)*g(cat) 1*h-1.
Comparing the product distributions (see Figure 6.1), it may be noted that OMEn yield is
decreasing with increasing n – a typical feature of chain-growth reactions – and that products
(OMEn) and by-products (MeFO, DME) are formed in varying ratios. While the latter may
appear trivial, this is not commonly the case in the analogous liquid phase batch reactions
where equilibrium compositions are reached irrespective of the catalyst used (see Table 2.2.
Catalysts however vary in the time for reaching this equilibrium.68 The reversibility of the side
41 Preliminary catalyst screening
reactions was tested as described in chapter 5.1. It was confirmed that MeFO is formed
irreversibly while OME1 formation is reversible. It can therefore be supposed that the tested
catalysts differ in their activity towards the irreversible formation of MeFO and DME.
H-MOR-40, HPA/Al2O3 and Amberlyst 36 show the highest activity. However, the two latter
catalysts have a major drawback. Leaching of active species was observed, causing
contamination of the downstream components of the set-up. When the reactor was bypassed,
active species that had accumulated in the back pressure regulator caused transformation of
the feed stream (see Figure 6.1, residual activity).
Silicotungstic acid is water-soluble and it can be assumed that the heteropoly acid was leached
from the alumina support. In case of Amberlyst 36, which is a sulfonic acid functionalised ion-
exchange resin, the downstream contamination is presumably caused by decomposition of
sulfonic acid groups. It appears that the reaction temperature of 130 °C is too close to the
maximum operating temperature of 150 °C specified by the supplier. The decomposition of
sulfonic acid was confirmed by preparation of sulfonic acid functionalised silica (SBA-15-
SO3H, see chapter 11.2.2). Accordingly, residual activity occurred after testing the material.
Potentially, sulphur trioxide can be released. It must be noted that the residuals in the set-up
show good activity and an excellent selectivity towards OME. Even though a series of tests
were performed, the residuals could not be accumulated and extracted nor could their nature
be fully elucidated. The investigations involved extensive maintenance of the set-up. It was
therefore refrained from further testing of supported heteropoly acids and ion-exchange resins.
Instead, a systematic investigation of zeolites for gas-phase OME synthesis was targeted,
which is described in chapter 7.
OME synthesis over zeolite catalysts 42
7 OME synthesis over zeolite catalysts1
7.1 Catalyst screening
On the basis of the promising performance of the preselected zeolite H-MOR-40 in the
preliminary screening described in the previous chapter and also owing to the well-known
variability of zeolitic materials with regards to structure and acidity, a systematic study of
OME synthesis over zeolites was envisaged. This study included a screening of commercial
and synthesised zeolitic materials and a detailed study of the deactivation and regeneration
behaviour using the two best performing benchmark catalysts.
In the zeolite screening, materials with four different framework types and varying
SiO2/Al2O3-ratios were chosen. The selected zeolites were used in protonated form. In analogy
to the before mentioned catalyst H-MOR-40, the catalysts are named to indicate the proton
form (prefix H-), the framework type (three letter code) and SiO2/Al2O3-ratio (suffix). Three
samples of zeolite Y (H-FAU-12/129/340), two of zeolite Beta (H-BEA-35/150), three of
ZSM-5 (H-MFI-27/90/∞, the latter will be referred to as Silicalite-1 throughout the study) and
two of Mordenite (H-MOR-14/40) were tested under the conditions derived in chapter 5. In
Table 7.1, an overview of structural parameters of the included framework types is presented.
Further information about the employed materials and activation procedures is presented in
chapter 11.1.3, 11.2.3 and 11.3.1.
Table 7.1: Characteristics of selected zeolite framework types.125
frameworktype threeletter code
exemplary trivial namesof related materials
maximum diameter of asphere that can diffuse
along / Å
largest poreopening ring
sizea
channeldimension-
nalityb
MFI ZSM-5 a: 4.70, b: 4.46, c: 4.46 10 3DMOR Mordenite a: 1.57, b: 2.95, c: 6.45 12 2D (1D)c
FAU Faujasite, Y-zeolite a: 7.35, b: 7.35, c: 7.35 12 3DBEA Beta zeolited a: 5.95, b: 5.95, c: 5.95 12 3D
a number of TO4 units connected to a ring at the pore openingb including channels with pore opening ring sizes larger than 6c transport along one axis is structurally hindered, therefore effectively 1D122
d partially distorted materials, parameters given for idealised framework
1 The major part of this chapter was published in Gas-phase synthesis of oxymethylene ethers over Si-rich zeolites, A. Grünert,P. Losch, C. Ochoa-Hernández, W. Schmidt and F. Schüth, Green Chem., 2018, 20, 4719-4728. Copyright 2018, RoyalSociety of Chemistry. In the following text, numerous quotations and reproductions of figures and tables from the publicationare included, but will not be marked individually.
43 OME synthesis over zeolite catalysts
The results of the zeolite catalyst screening are presented in Figure 7.1. Similar to the general
catalyst screening discussed in chapter 6, varying product distributions and conversion levels
are observed. It is remarkable that there is a trend in the zeolite catalyst performance. For all
four structural classes of zeolites, an increase in selectivity to OME and a decrease in
conversion are observed with increasing SiO2/Al2O3 ratio (SAR). At increased SAR, the
amount of Al and hence the amount of Brønsted-acidic protons is decreased.
An influence of SAR on catalyst performance has been reported for H-ZSM-5,103, 113
H-MCM-22 112 and Al-SBA-15 107 when OME was synthesized in batch-mode from OME1 or
MeOH and trioxane. In these cases however, a maximum in OME yield was generally
observed with conversion drastically decreasing at higher SAR due to insufficient release of
formaldehyde by acid catalysed decomposition of trioxane. In our study, no constraints by
trioxane decomposition exist and we have confirmed the trend over a wide range of SAR and
for a broad range of samples.
Figure 7.1: Catalyst screening: Initial selectivity and conversion of zeolitic catalysts determined in the interval of 40 - 70 min.reaction time. Reaction conditions: 10 bar, 130 °C, 0.5 g of catalyst, 100 mL/min inert gas flow, 14 μL/min FA/MeOHsolution feed. WHSVFA: 1.1 g(FA)*g(cat) 1*h-1.
7.2 Correlation between acid site properties and catalyst performance
In order to study the suggested correlation of catalyst performance and the properties of its
acid sites, temperature programmed desorption of ammonia (NH3-TPD) was carried out for all
materials under investigation (Figure 12.3 to Figure 12.6). It has been discussed for liquid-
OME synthesis over zeolite catalysts 44
phase OME synthesis over different zeolites that moderately strong acid sites are best suited
for OME syntheses. 103, 105 This cannot be confirmed in case of gas-phase synthesis from
MeOH and FA. In Figure 7.2, conversion and OME yield are presented as a function of the
total amount of ammonia desorbed in the NH3-TPD measurement, the latter being related to
the total amount of acid sites in the zeolite. In addition to the zeolitic catalysts, an amorphous
siliceous reference material (fumed silica Aerosil 200) is included. In accordance with the
above described correlation between SAR and conversion, an increased amount of acidic sites
correlates to higher conversion for zeolitic samples (Figure 7.2, left). It is also evident that
amorphous silica is not active. The NH3-TPD curves show relatively broad and/or flat signals.
Therefore, a deconvolution into low- and high-temperature contributions was not performed.
Figure 7.2: Left: Conversion and right: OME yield as a function of total amount of ammonia desorbed. Filled symbols denotezeolitic catalysts; the hollow symbol indicates the siliceous reference sample. Suffixes at H-MOR-40 samples indicatecalcination temperature as discussed below.
When the OME yield is related to the total amount of acid sites (Figure 7.2, right), zeolites
with a low acid site concentration seem to perform best. The highest OME yields of 42% and
43% are achieved by H-MOR-40_350 and Silicalite-1, respectively. The suffix refers to the
calcination temperature. Silicalite-1 is a siliceous zeolitic material that is characterized by the
presence of only very weakly acidic silanol groups (not detected in NH3-TPD). The described
high activity of Silicalite-1 is unexpected. Conventionally, classical Brønsted acid sites created
by Si-O-Al bridges, or Lewis acid sites are thought to be responsible for the formation of
OME. Since these are absent in Silicalite-1, another active site than hitherto thought must be
responsible for the high activity of this catalyst. The amorphous silica used as a reference has
no catalytic activity.
45 OME synthesis over zeolite catalysts
Figure 7.3: FTIR spectra of the pyridine stretching vibration region for a) MFI-27 and b) MOR-14 based materials at differentdesorption temperatures: i) 150 °C, ii) 250 °C and iii) 350 °C. Above: H-form zeolites, below: Na-form zeolites.
In order to substantiate the finding that Brønsted acid sites are not necessary to catalyse the
formation of OME in the gas-phase, two Al-containing zeolite catalysts were prepared in their
sodium form. For this purpose, the respective zeolite in ammonia form was ion-exchanged
with sodium nitrate and subsequently calcined (see chapter 11.3.2). The completion of the
sodium exchange was verified via FTIR spectroscopy using pyridine as a probe molecule.
Indeed, the stretching vibrations of pyridine interacting with Brønsted acid groups at 1635 and
1545 cm-1 vanished upon ion-exchange (see Figure 7.3 a). The bands present in the spectra of
the exchanged samples are typical for pyridine adsorbed on Na-zeolites.162 In the catalytic
tests, both materials showed a significantly improved performance resulting in an increase of
OME yield of as high as 38% in case of the Na-MFI-27 zeolite (see Figure 7.4).
As mentioned above, the product ratio is influenced by the activity of the catalysts towards the
irreversible formation of by-products. The observations that the formation of by-products is
suppressed by Na-exchange in Al-containing zeolites and that Silicalite-1 shows high OME
selectivity suggest that by-product formation may be related to the presence of strong
Brønsted acid sites. Weakly acidic sites such as silanol-groups in framework defects or at pore
mouths seem to provide sufficient acidity for the formation of OME. Besides, the presence of
weakly Lewis acidic sodium ions in the framework does also not have an adverse impact on
the OME selectivity.
1650 1575 1500 1425 1350
1595
1623
(iii)(ii)(i)
Na-MFI-27
Abs
orba
nce
(a. u
.)
Wavenumber (cm-1)
0.5
H-MFI-27
1635
1545
1455
1442
(i)(ii)(iii)
1650 1575 1500 1425 1350
159115
9916
20
(iii)(ii)(i)
Na-MOR-14
Abs
orba
nce
(a. u
.)Wavenumber (cm-1)
0.5
H-MOR-14
1633
1544
1454
1443
(i)
(ii)(iii)
a) b)
OME synthesis over zeolite catalysts 46
Figure 7.4: Initial selectivity and conversion of H- and Na-form zeolites determined in the interval of 40 - 70 min. reactiontime. Reaction conditions: 10 bar, 130 °C, 0.5 g of catalyst, 100 mL/min inert gas flow, 14 μL/min FA/MeOH solution feed,WHSVFA: 1.1 g(FA)*g(cat) 1*h-1.
When discussing the acidic properties of zeolites, it is also important to consider the influence
of extra-framework aluminium (EFAl), which is typically characterized by Lewis acidity. The
influence of the presence of EFAl on the formation of OME from MeOH and FA was
exemplarily studied using H-MOR-40. In a series of H-MOR-40 material calcined at varying
calcination temperatures, emergence of EFAl was induced at temperatures above 350 °C. This
was evidenced by 27Al-MAS-NMR (Figure 7.5).
The pristine H-MOR-40 shows mainly tetrahedrally-coordinated Al (signal centred at 57 ppm)
and only little Al in octahedral environment (signal centred at 0 ppm). Upon temperature
treatment, an increase in the asymmetric broadening of the signal related to tetrahedral
framework indicates the formation of Al in distorted tetrahedral environment and/or penta-
coordinated Al. Furthermore, a rise in the peak at 0 ppm and the additional emergence of a
broad peak centred at -5 ppm, assigned to various Al species in octahedral environment,
indicate the removal of Al from the mordenite framework and the formation of EFAl
species.163 When the sample calcined at 550 °C was washed with oxalic acid, which is known
to dissolve primarily EFAl species, the content of Lewis acid sites could be reduced.
47 OME synthesis over zeolite catalysts
Figure 7.5: Al-MAS-NMR spectra of H-MOR-40: pristine, calcined at 350 °C, 450 °C, 550 °C and H-MOR-40 calcined at550 °C with subsequent acid wash using oxalic acid (OA). Stacked spectra (a) and overlapping spectra (b and c). Signals arenormalized to the signal at 57 ppm.
The change in the ratio of Brønsted- to Lewis-acidity as a result of EFAl formation was
confirmed by Pyridine-FTIR measurements (Table 7.2 and Figure 12.7). The concentration of
Brønsted and Lewis acid sites was quantified by analysis of the pyridine stretching vibrations
corresponding to interaction with Brønsted acid sites at 1545 cm-1 and Lewis acid sites at 1455
cm-1. Additionally, information about the strength of the acid sites could be gained by
adsorption of pyridine at different temperatures. As expected, a decrease in the ratio of
Brønsted to Lewis acidity with increasing calcination temperature is observed. Notably, a
constant Si/Al ratio was determined for all FTIR measurements, which is an indication for
good comparability of FTIR results over the series of studied catalysts. The Si/Al ratio
calculated from FTIR data is commonly lower than when calculated from aluminium content
as not all of the Al atoms are probed. For example, Al may be related to a very weak site that
does not retain pyridine at the adsorption temperature of 150 °C. Alternatively, it may be
buried inside an extra-framework cluster and is therefore not accessible to pyridine.
OME synthesis over zeolite catalysts 48
Table 7.2: Acid sites concentration of selected samples after pyridine adsorption at 150 °C (CB: concentration of Brønstedacid sites; CL: concentration of Lewis acid sites). Suffixes denote the calcination temperature. Extinction coefficients obtainedfrom reference 164.
pyridine desorptiontemperature (°C)
CB (mmol/g) CL (mmol/g) B/L Si/Ala
H-MOR-40_350ºC150 0.34 0.09 3.8
30250 0.29 0.08 3.6
350 0.18 0.06 3.0
H-MOR-40_450ºC150 0.30 0.11 2.7
30250 0.25 0.09 2.8
350 0.14 0.07 2.0
H-MOR-40_550ºC150 0.28 0.15 1.9
28250 0.26 0.13 2.0
350 0.18 0.10 1.8a Calculated at 150 ºC
Figure 7.6: Initial conversion and selectivity of H-MOR-40 as a function of calcination temperature.
The H-MOR-40 samples were also characterized by NH3-TPD (Figure 12.8). An increased
amount of ammonia desorbed in the high-temperature range of 500 - 700 °C is evident in the
curves of samples calcined at 450 and 550 °C as compared to 350 °C suggesting that upon
temperature treatment stronger acid sites were created. These could be due to strongly acidic
EFAl sites and/or Brønsted acid sites with increased acidity due to interaction with EFAl.127
49 OME synthesis over zeolite catalysts
The effect of EFAl formation and the resulting rise in the Brønsted- to Lewis-acid ratio is
reflected in the catalytic performance of H-MOR-40. A significant drop in OME selectivity
was observed when calcination temperatures above 350 °C were employed (Figure 7.6).
In summary, one may conclude that three different acidic species in zeolites – namely
Brønsted acid sites, Lewis acidic EFAl species as well as silanol groups – all affect the
catalytic performance of the zeolites. This complex interplay of acidic sites along with the
competition of OME formation with irreversible side-reactions render it difficult to exactly
determine specific contributions of each type of acid site. However, the general conclusion can
be drawn that catalysts characterized by a low number of Brønsted and/or EFAl acid sites
show better performance and that weakly acidic species such as silanol groups are sufficient to
catalyse the OME formation.
7.3 Influence of particle size and external surface area
Figure 7.7: Left: Mean particle size and standard deviation for a selection of commercial zeolites. Right: Conversion as afunction of external surface area.
In order to rule out an effect of crystallite size, scanning electron microscopy (SEM)
micrographs and in some cases additional transmission electron microscopy (TEM) images of
catalysts tested in the screening were collected. Exemplarily, an SEM image and histogram of
H-FAU-12 are presented in Figure 12.9 and Figure 12.10. However, the size distribution of
the commercial materials was too broad to allow reasonable correlation of particle size and
catalyst activity (see Figure 7.7, left).
OME synthesis over zeolite catalysts 50
Additionally, external surface areas were determined from nitrogen sorption isotherms via
t-plot analysis and plotted against conversion (Figure 12.11) and OME yield (Figure 7.7,
right). However, no clear correlation with the external surface area was evident.
7.4 Adaptation of reaction conditions
In order to further investigate the catalyst performance for OME gas-phase formation, the two
best performing zeolites from the screening were tested under adapted conditions. For both
materials, an improved OME yield was achieved when the weight hourly space velocity
(WHSV) was increased from 1.1 to 6.4 g(FA)/g(cat)-1*h-1 by adapting reactant mass flow as well
as reactant partial pressure (Figure 7.8). Under the mentioned conditions, total OME
selectivity reaches 95% at a conversion of 49% (H-MOR-40) or 47% (Silicalite-1) and, in
contrast to screening conditions, OME3 was detected. Notably, trioxane is also observed as a
by-product. However, the amount of trioxane formed decreases strongly within the first 60
min. reaction time and subsequently remains at a stable level. Initial conversion and selectivity
under adapted conditions was therefore determined at 60-90 minutes reaction time.
Figure 7.8: : Initial conversion/selectivity of H-MOR-40 and Silicalite-1 at increased WHSV and reactant partial pressuredetermined in the interval of 60 - 90 min. reaction time. Reaction conditions: 10 bar, 130 °C, 1 g of catalyst, 400 mL/min inertgas flow, 168 μL/min FA/MeOH solution feed. WHSV for formaldehyde: 6.4 g(FA)/g(cat)-1*h-1.
51 OME synthesis over zeolite catalysts
7.5 Catalyst deactivation and regeneration
Whereas catalytic properties of Silicalite-1 and H-MOR-40 with regards to conversion and
product distribution are very similar, a difference is observed in deactivation behaviour. In
tests that were performed under the same reaction conditions as the catalyst screening,
deactivation proceeded much slower for H-MOR-40 than for Sillicalite-1 (Figure 7.9, left).
The deactivation onset was defined as the time at which conversion has decreased to 85% of
the steady-state conversion level. Deactivation experiments were repeated three times and the
average deactivation onset time was determined to be 38.3 h for H-MOR-40 and 11.1 h for
Silicalite-1 with a broader spread of data in case of H-MOR-40 compared to Silicalite-1. It has
to be noted that after the defined deactivation onset, the conversion drops with a smaller slope
in case of H-MOR-40 as compared to Silicalite-1.
Figure 7.9: Left: Exemplary deactivation curve: Conversion and OME selectivity as a function of time for H MOR 40 andSilicalite-1. The defined deactivation onset is indicated as a dotted grey line. Reaction conditions: 10 bar, 130 °C, 0.5 g ofcatalyst, 100 mL/min inert gas flow, 14 μL/min FA/MeOH solution feed WHSV for formaldehyde: 1.1 g(FA)/g(cat)-1*h-1.Right: TG-MS curve of Silicalite-1 measured in argon.
Several factors can affect the starting point of deactivation. For example, the deactivation
mechanism will have a major impact on the deactivation behaviour of the catalyst. As the
formation of OME is a chain growth reaction, formation of higher, non-volatile OME
homologues in small quantities is expected and could lead to a surface, pore or active site
blocking of the catalyst. In the TG-MS curve of Silicalite-1 measured in an inert gas stream
the release of FA and MeOH along with CO2 and H2O in the range of 170 – 350 °C is evident
(Figure 7.9, right). Similar data is obtained when measured in a stream of air (Figure 12.12).
For H-MOR-40, the mass loss occurs in several stages, but also in this case, the release of the
OME synthesis over zeolite catalysts 52
starting materials FA and MeOH along with CO2 and H2O is observed (Figure 12.13 and
Figure 12.14).
The release of FA and MeOH can either be related to a release of monomeric FA and MeOH
from the pores and/or active sites, or to the presence and decomposition of non-volatile OME
homologues or other non-volatile FA-containing species such as paraformaldehyde. When
pore or surface blocking is discussed as possible deactivation mechanism, several factors can
be considered effective to result in the differences in deactivation onset between Silicalite-1
and H-MOR-40. The two samples have a pronounced difference in crystallite sizes and size
distribution (Silicalite-1: approx. 42 x 8 μm, H-MOR-40 large size distribution with an
average of about 0.15 μm). The smaller external surface area of the Silicalite-1 could result in
a faster blocking of the surface or pore entrances. A further parameter possibly influencing the
deactivation behaviour is the difference in diameters of the micropores (ring size of largest
channel: 12 (MOR) vs. 10 (MFI); computed as 6.45 Å for MOR vs. 4.7 Å for MFI).125
Both catalysts could successfully be regenerated. Silicalite-1 was calcined in air at 550 °C to
restore activity. For H-MOR-40, such a treatment would be too harsh and result in decreased
OME selectivity (vide supra), and so the mordenite sample was regenerated in inert gas flow
at 350°C. Whether such a treatment would also be sufficient for the Silicalite-1 was not
explored. As a proof of principle, the restoration of full performance was demonstrated two
times for each catalyst (Figure 12.15).
7.6 Comparison of siliceous materials
As mentioned above, the amorphous silica reference material (Aerosil 200) was found to be
inactive for OME synthesis, while Silicalite-1 (crystalline zeolite with MFI structure) is one of
the best performing catalysts in this study. In order to investigate the difference between the
two siliceous materials, a FTIR-DRIFTS adsorbate study was performed.
For spectra of activated samples see Figure 12.16. The pristine Aerosil 200 shows only
isolated silanol groups [3746 cm-1]165. Signals in the IR spectrum of Silicalite-1 can be
attributed to unperturbed internal silanol groups [3723 and 3675 cm-1]166 and H-bonded
internal silanol groups and silanol groups interacting with water [broad signal at 3000 - 3600
cm-1]. No isolated external silanols are observed, which can be attributed to the large
dimensions of the Silicalite-1 crystals that feature a very low external surface area compared
53 OME synthesis over zeolite catalysts
to the bulk volume. At the activation temperature, which is the maximal temperature
achievable in the DRIFTS set-up, water is not completely removed as evident from the
presence of a signal at 1634 cm-1 167 and the broadness of the peak at 3000 - 3600 cm-1. A
harsher treatment to completely remove water was not applied, as water being a by-product of
OME formation will also always be present under reaction conditions.
Figure 7.10: Difference spectra of Aerosil 200 and Silicalite-1 after adsorption of probe molecules. For non-substractedspectra, refer to Figure 12.17.
After exposure of samples to FA and MeOH vapour, no additional signals could be observed
in case of Aerosil 200 (Figure 7.10). The signal related to external silanol groups shows
decreased intensity, indicating that there is interaction with adsorbed species. As the reactant
molecules do not seem to adsorb on the Aerosil 200 surface, this decrease might be assigned
to adsorption of additional water molecules. In case of Silicalite-1, a distinct pattern of signals
in the range 2770 - 3000 cm-1 and a group of weak intensity signals at 1449, 1465 and
1475 cm-1 appear upon adsorption of the vapour containing FA and MeOH. Notably, the
spectrum after adsorption of OME1 shows the same features. The OME1 features agree well
with literature data (cf. liquid OME1 spectrum)168. As a reference, pure MeOH was adsorbed
on Silicalite-1. In the considered range, signals at 2950 and 2846 cm-1 are present in the
difference spectrum after adsorption. Considering IR data of formaldehyde from literature
[NIST database: 2785, 2850 and 2995 cm-1]169, the pattern arising after exposure to FA and
OME synthesis over zeolite catalysts 54
MeOH vapour cannot be explained by a superposition of FA and MeOH signals. We assume
that the reactants FA and MeOH have already reacted to OME1 at 40 °C. This is in good
agreement with reports from literature describing liquid phase OME synthesis at temperatures
as low as 50 °C.66
At this point, a clear assignment of activity to certain silanol species in Silicalite-1 is difficult.
In case of the Beckmann rearrangement of cyclohexanone oxime to ε-caprolactam, for which
Silicalite-1 is also highly active and selective, internal silanol nests as well as external silanol
groups are discussed to be the active species.128, 170 The data obtained in this study does not
allow such a straightforward interpretation as IR signals for silanol nests are not well resolved
due to the presence of water. Furthermore, the decrease in signal intensity upon adsorption
could only be assigned to unperturbed internal silanol groups.
From the FTIR-DRIFTS adsorbate study, a clear difference in the adsorption behaviour of
Silicalite-1 compared to amorphous silica was shown. We assume that the high adsorption
potential as present in micropores of the crystalline zeolite may be a key factor for activity in
OME synthesis.
7.7 Conclusions
In summary, a broad range of zeolites was tested in the gas-phase synthesis of OME from
methanol and formaldehyde. It was demonstrated that catalysts characterised by a low number
of Brønsted acid sites and/or EFAl show a better performance and that very weakly acidic
species such as silanol groups can catalyse OME formation with a lower tendency for by-
product formation than strong acid sites.
With respect to catalytic activity, Silicalite-1 and H-MOR-40 showed the best performance.
Both catalysts allow producing OME with selectivity as high as 95%. A deactivation study
showed that H-MOR-40 features increased long-term stability compared to the all-silica
material Silicalite-1, while both catalysts could be fully regenerated by thermal treatment.
55 OME synthesis over supported phosphoric acid
8 OME synthesis over supported phosphoric acid2
In this section, phosphoric acid supported on carbon was investigated as an alternative to
zeolite catalysts for gas-phase OME synthesis. In established supported phosphoric acid
catalysts, for which silica is used as a support, the presence of various phosphor containing
species including silicon phosphates 134 makes a correlation of structure or loading with
activity difficult. When phosphoric acid is supported on a porous carbon (H3PO4/C, see Figure
8.1) and used without thermal treatment at elevated temperatures, no mixed phases or
phosphorylation of the support is expected to occur. This renders analysis, e.g. via 31P MAS
NMR analysis, significantly more simple. Furthermore, the H3PO4/C catalysts can be
synthesised from cheap and readily available materials via simple synthesis protocols. To date,
only few reports of carbon supported phosphoric acid catalysts have been published.138
Alumina is not considered as a support as it suffers from formation of inactive aluminium
phosphate.
Figure 8.1: Schematic representation of supported phosphoric acid catalysts employed in this work.
In the following, the characterisation of prepared H3PO4/C catalysts will be presented.
Subsequently, the activity of H3PO4/C catalysts in the formation of oxymethylene ethers from
methanol and formaldehyde and the activity of related hydrogen phosphates H2PO4- and
HPO42- is evaluated. As zeolites constitute a common alternative to phosphoric acid based
systems in industrial processes,135 the performance of H3PO4/C is additionally compared to a
benchmark zeolite catalyst.
2 The major part of this chapter will be published as Carbon Supported Phosphoric Acid Catalysts for Gas-Phase Synthesis of
Diesel Additives, A. Grünert, W. Schmidt and F. Schüth, to be submitted.
OME synthesis over supported phosphoric acid 56
8.1 Catalyst Characterisation
For the preparation of supported catalysts, it is of interest to firstly study the textural properties
of the chosen support. In this study, the commercial granular activated carbon TC303 supplied
by Silcarbon was used. The nitrogen physisorption isotherm of the pristine granular carbon
(denoted as C-granule) shows typical features of a micro- and mesoporous material (see
Figure 8.2). While the steep increase at low N2 pressure indicates the presence of micropores,
the occurrence of a hysteresis loop is typical for mesoporous materials. Accordingly, the shape
of the hysteresis loop is characteristic for materials containing micro- and mesopores and
corresponds to a H4-type hysteresis loop in IUPAC classification,.171 Furthermore, a total pore
volume of 1.1 cm3/g was determined from physisorption data. From thermogravimetric
analysis (see Figure 12.18), a water content of 6.2% and ash content of 2.1% of the granular
carbon, pretreated as described in chapter 11.3.1, was determined.
Figure 8.2: N2 physisorption isotherm of granular carbon support and the impregnated sample 0.9_H3PO4/ C.
The impact of phosphoric acid impregnation on the sorption properties of the materials was
exemplarily studied using catalyst 0.9_H3PO4/C. The impregnated samples are named
x_H3PO4/C, the prefix x indicating the H3PO4 loading in [g H3PO4 /g C]. The filling of a large
share of pores upon impregnation is reflected by a pronounced decrease of total pore volume
from 1.1 to 0.3 cm3/g. Accordingly, the BET surface area decreased from 1573 m2/g to
203 m2/g. As BET surface area has a limited physical validity for microporous materials, it is
only specified as a means for comparison of the materials.
57 OME synthesis over supported phosphoric acid
For the interpretation of N2-physisorption of supported phosphoric acid, it should be kept in
mind that H3PO4 is solid at measurement temperature (-196 °C), but will be liquid under
reaction conditions (130 °C, melting point H3PO4: 42 °C).172 The decrease of pore volume
evidenced in physisorption analysis hence is not regarded as a pore blocking, but rather gives
information about the filling degree of the pores.
The distribution of phosphoric acid within the carbon support was studied via phosphorus
elemental mapping. The micrographs presented in Figure 8.3 were collected using a scanning
electron microscope (SEM) coupled with energy dispersive X-ray spectroscopy (EDX). It
could be confirmed that the active phase is well distributed within the support matrix.
Figure 8.3: EDX-SEM micrographs of 0.9_H3PO4/C. a)-c): Overview of a representative granule and d)-f) close-up view ofgranule edge. Micrographs show a)/d) secondary electron image b)/e) carbon elemental map and c)/f) phosphorus elementalmap.
In 31P MAS NMR spectra of the as synthesised catalysts, two lines are present (see Figure
8.4). The line at about 0 ppm can readily be assigned to ortho-phosphoric acid (H3PO4) as the
spectra are referenced to 85% H3PO4. The second line at about –13 ppm is related to a
condensed phosphoric acid species, supposedly pyrophosphoric acid. As the chemical shifts of
condensed phosphates are dependent on the local environment,173 it is not surprising that
different chemical shifts have been reported for supported pyrophosphoric acid (H4P2O7)
depending on the support material. While spectra of phosphated zeolites feature lines at both
–5 ppm and –13 ppm,174 in spectra of the SPA catalyst (H3PO4/SiO2) the line at –5 ppm is not
OME synthesis over supported phosphoric acid 58
observed.134 It may be supposed that SPA is a valid reference to H3PO4/C. Hence, the
observed line at –13 ppm indicates the presence of pyrophosphoric acid. The absence of
further lines suggests that the sample contains no polyphosphates.
Figure 8.4: Stacked 31P MAS NMR spectra of H3PO4/C catalysts with varying loading. Positions of spinning side bands aremarked with asterisks. Prefix denotes loading in [g H3PO4/ g C].
As the integrals of the lines can be assumed to be proportional to the amount of phosphorus
(with 1 P per H3PO4 and 2P per H4P2O7), the major share of phosphorus is present in the form
of phosphoric acid.
Under reaction conditions, the catalyst is exposed to gaseous polar components including
water at elevated temperatures (130 °C). Both ortho- and pyrophosphoric acid have melting
points below the reaction temperature (H3PO4: 42.3 °C, H4P2O7: 71.5 °C) and are hygroscopic.
It is therefore expected that, firstly, the active components melt upon preheating the catalyst
and, secondly, a concentrated solution is formed on the catalyst in the presence of water. As
the condensation of phosphoric acid to pyrophosphoric acid is a reversible reaction,
pyrophosphoric acid can undergo hydrolysis to release ortho-phosphoric acid.172 This may be
expected to also occur under reaction conditions.
A linear correlation was found when the amount of phosphorus detected via 31P MAS NMR,
expressed by the integral over the range of [80 ppm, –80 ppm], was related to the expected
amount, as calculated from incipient wetness impregnation, for a range of different samples
59 OME synthesis over supported phosphoric acid
(see Figure 12.19). This indicates that the complete amount of phosphorus is detected via 31P
MAS NMR.
It was not viable to use an external phosphorus standard for comparison due to very long
relaxation times of phosphates. For example, Na2HPO4 requires significantly more than 10
minutes relaxation time per scan (see Figure 12.20). Even ammonium dihydrogen phosphate
(NH4H2PO4), which is a typical standard for quantification in 31P MAS NMR, has a relaxation
time of more than 15 minutes per scan. For the purpose of this study, it was sufficient to
establish a linear correlation of NMR integral to phosphorus loading.
It was not feasible to use methods for acid site characterisation in analogy to the study of
zeolites presented in chapter 7. In both cases, the complete removal of water by thermal
treatment is a prerequisite for collection of meaningful data. In case of H3PO4/C, condensation
of orthophosphoric acid to pyro- and polyphosphoric acid is expected to occur upon thermal
activation. The species are characterised by differences in acidity (H3PO4: pKa1 of 2.16 and
H4P2O7: pKa1 of 0.91),172 which renders the characterisation via NH3-TPD and pyridine-FTIR
difficult.
8.2 Preliminary studies of exemplary H3PO4/C catalyst
Prior to catalytic tests of the impregnated catalysts, the inertness of the support was confirmed.
In a blank test run under reaction conditions, no conversion over the granular carbon was
evidenced. However, it was observed that the carbon material strongly interacts with the
reagents methanol and formaldehyde (see Figure 12.21). In the first data point after the start of
the reaction, it is normal to see a drop in reactant concentration due to inert gas flushing out of
the reactor. However, the detected reagent concentrations increase only slowly thereafter,
reflecting the ongoing adsorption of reagents inside the porous carbon material. It should be
noted that the carbon balance was calculated analogously for all test runs and the herein
described behaviour was only observed to a marginal extent when a reaction occurred.
As a model H3PO4/C catalyst, a material with a loading of 0.9 g H3PO4/ g C was prepared. It
was used to test the general suitability of H3PO4/C catalysts in the gas-phase synthesis of
OME from MeOH and FA. Conversion levels of 47% and OME selectivity of 95% were
measured at moderate WHSVFA = 1.1 (see Figure 8.5, left). OME1, OME2 and the side product
methyl formate was formed. While the initial conversion is lower as compared to benchmark
OME synthesis over supported phosphoric acid 60
zeolites (see chapter 7), the initial selectivity is improved, leading to a comparable initial OME
yield.
The moderate acid strength of phosphoric acid (pKa1 = 2.1) appears to be sufficient to reach
the benchmark performance. In analogy to previously studied series of zeolite catalysts, the
absence of strongly acidic groups prevents the excessive formation of the by-product methyl
formate and the occurrence of dimethyl ether.
The experiences of the preliminary solid acid catalyst screening described in chapter 6
highlighted the need to monitor leaching of active sites. A blind run with an empty reactor was
therefore conducted right after testing the model catalyst. No residual activity due to
contamination of downstream set-up components was observed.
8.3 Impact of H3PO4 loading
In order to test the influence of phosphoric acid loading on the catalyst performance, two
further catalysts with varying phosphoric acid loading were prepared, representing a range of
0.04 to 0.9g H3PO4/ g C.
Figure 8.5: Left: Initial conversion and selectivity after 1 h reaction time of H3PO4/C catalysts with varying phosphoric acidloading. Reaction conditions: 500 mg catalyst, 10 bar, 130 °C, WHSVFA = 1.1. Right: Initial conversion and selectivity after 1h reaction time of 0.9_H3PO4/C catalysts at WHSV for formaldehyde of 1.1 g(FA)/g(cat)-1*h-1 and 42.7 g(FA)/g(cat)-1*h-1.
In contrast to zeolites, a significant change in acid strength upon variation of acid
concentration is not expected for supported phosphoric acid catalysts. This can be rationalised
61 OME synthesis over supported phosphoric acid
by the assumption that unlike protons in zeolites, the phosphoric acid is mobile and therefore
the individual molecules are not significantly influenced by the local environment.
The catalysts showed similar performance over the whole range of phosphoric acid loading
(see Figure 8.5, left). For all test runs, the conversion and selectivity reached a constant level
after 30 minutes of reaction time and showed no change until the end of measurement after
1.5 h reaction time. It can be regarded as an (initial) steady-state conversion/selectivity. The
independence of performance with respect to the active phase loading may be an indication
that the reaction is running close to equilibrium.
In order to evaluate the sensitivity of the reaction towards decreased residence times, the
exemplary catalyst 0.9_H3PO4/C was also tested at the maximal WHSVFA that can be realised
in the test set-up without raising the reactant concentration (WHSVFA = 42.7 h-1). The catalyst
in its granular form showed a drop in conversion to 31%. Additionally, the side reaction
towards methyl formate was supressed (see Figure 8.5, right).
The observed drop in conversion upon increase in WHSV indicates that the transformation is
not running in equilibrium under the respective conditions. This can be a consequence of
reaching the limit of the intrinsic reaction rate or of running in a mass transfer limited regime.
The latter may be caused by microscopic effects within the catalyst granules or by
macroscopic effects such as channel formation in the catalyst bed. A hint towards mass
transfer limitations can be a change in catalyst performance upon change of catalyst particle
size. When the catalyst granules were ground to a fine powder prior to testing, the conversion
improved and a comparable performance to the moderate WHSVFA recurred. This is only a
first indication towards the cause of the observed drop in conversion. It may, however, be
concluded that the powdered catalysts apparently react in equilibrium even at high space
velocity. For diverse reasons, such as improved handling and reproducibility, better
comparability with previous results and to avoid potential interference with mass transfer or
other limitations, all further tests were carried out at moderate weight hourly space velocity
(WHSVFA = 1.1 h-1).
8.4 Sodium phosphates
As phosphoric acid is a polyprotic acid, it is of interest to also study the contributions of the
related proton donating species, namely dihydrogen phosphate (H2PO4-) and hydrogen
phosphate (HPO42-). Their varying deprotonation barriers are reflected in the different
OME synthesis over supported phosphoric acid 62
dissociation constants of phosphoric acid of pKa1 = 2.16, pKa2 = 7.21 and pKa3 = 12.32 (at
25 °C).172 Monosodium phosphate and disodium phosphate were used as representative salts.
A series of catalysts containing equimolar amounts (700 μmol/g C) of H3PO4, NaH2PO4 or
Na2HPO4, respectively, was prepared by incipient wetness impregnation of the respective
components.
Out of the series of catalysts, H3PO4 shows the highest activity in OME formation. In
comparison to H3PO4/C catalysts, activity of the sodium phosphate based catalysts is
significantly reduced (Figure 8.6, left). Conversion drops successively from H3PO4 to
Na2HPO4. For NaH2PO4/C, the conversion is decreased to a level of 10%. The material
Na2HPO4/C is inactive in the studied reaction.
Figure 8.6: Initial conversion and selectivity of granular carbon loaded with 700 μmol /g C of phosphoric acid or sodium (left)and Na2HPO4/C catalysts with different loading (right) after 1h reaction time. Reaction conditions: 500 mg catalyst, 10 bar,130 °C, WHSVFA = 1.1.
The sodium exchange also influences the catalyst selectivity. In case of NaH2PO4/C, the
irreversible formation of methyl formate from formaldehyde is more pronounced which leads
to a decrease in overall OME selectivity. Interestingly, a larger share of OME2 is formed as
compared to the H3PO4/C system. The product distribution of Na2HPO4/C is not meaningful as
the overall conversion was below 1% not allowing reliable quantification of reaction products.
63 OME synthesis over supported phosphoric acid
In analogy to the test runs using H3PO4/C, conversion and selectivity reached an (initial)
steady-state after 30 minutes of reaction time.
As the conversion over NaH2PO4/C is lower than over the H3PO4/C system, it may be argued
that the reaction does not reach equilibrium in this case. The conversion should hence be
sensitive to reaction conditions such as residence time and catalyst loading. Indeed, the
increase of NaH2PO4/C loading from 0.08 to 0.3 g/g C resulted in a doubling of conversion
and an increase in OME selectivity (see Figure 8.6, right).
8.5 Comparison with benchmark zeolite
In order to evaluate the general performance of the H3PO4/C system with respect to the well-
established group of zeolite catalysts, results were compared with those over H-MOR-40. The
catalyst H-MOR-40 was chosen as it shows a superior stability as compared to Silicalite-1.
Furthermore, H-MOR-40 is a classic Brønsted acidic zeolite and is hence more easily
compared to the Brønsted acidic phosphoric acid catalyst. The catalyst stability and
deactivation behaviour were chosen as parameters to be compared.
For a fair comparison, a similar amount of Brønsted acidic sites should be present in the
reactor. The total amount of acid sites of H-MOR-40 was determined via NH3-TPD to be
385 μmol acid sites per gram zeolite.175 An analogous characterisation of H3PO4/C catalysts
with NH3-TPD is difficult due to expected changes in the catalyst state upon thermal
activation. As reasoned above, phosphoric acid may be assumed to be the predominant active
species under reaction conditions. Therefore, the acid site concentration was directly related to
the phosphoric acid loading. It should be acknowledged that this comparison is based on the
before mentioned assumptions and will therefore not yield exact numbers, but acid site
concentrations in the same range.
A representative sample of H3PO4/C with 385 μmol acid sites /g sample was prepared by
dilution of the 0.3_H3PO4/C with the carbon support material. In order to achieve a
satisfactory mixing and to yield a particle size similar to H-MOR-40, the H3PO4/C sample was
ground in a mortar prior to catalytic testing.
In the deactivation study presented in Figure 8.7, the stability of the H3PO4/C catalyst was
identified to be superior to the benchmark zeolite H-MOR-40. The zeolitic catalyst reached
85 % of its steady-state conversion after 21 h reaction time and 50% after 36 h. Even though
OME synthesis over supported phosphoric acid 64
the same reaction conditions were applied as in the deactivation study described in chapter 7.5,
the catalyst lifetime is lower. This may be a result of the low reproducibility of the
deactivation curve of H-MOR-40, which has also been mentioned in chapter 7.5. In contrast to
the zeolite catalyst, the H3PO4/C catalyst kept 87% of its steady-state conversion up to the end
of the measurement at 95 h reaction time. The selectivity is hardly affected by the
deactivation.
Figure 8.7: Conversion and overall OME selectivity as a function of time for H3PO4/C and H-MOR-40 catalysts with the sameconcentration of acid sites. Reaction conditions: 500 mg catalyst, 10 bar, 130 °C, WHSVFA = 1.1.
In the previous study, pore blocking was argued to likely be a main cause for deactivation of
zeolitic catalysts.175 The tested zeolitic structures were purely microporous and therefore
susceptible to deactivation via pore blocking. In contrast, the H3PO4/C catalysts used in this
study have a micro- and mesoporous carbon matrix, which facilitates the access to the active
species. Furthermore, phosphoric acid as the active phase is in a liquid state of matter under
reaction conditions and is mobile, presumably leading to a good dispersion of the active phase.
Additionally, reagents may diffuse into the active phase. In this respect, it is not surprising to
observe deviating deactivation behaviour of the two fundamentally different solid acid
catalysts. Potentially, a combination of the described properties of supported phosphoric acid
is the basis for the deactivation resistance of the catalyst.
65 OME synthesis over supported phosphoric acid
8.6 Conclusions
Carbon supported phosphoric acid catalysts are easily synthesised from cheap materials. Due
to the presence of a limited number of phosphorus-containing species, the catalysts can readily
be analysed using 31P MAS NMR.
In this section, the activity of H3PO4/C catalyst in the gas-phase synthesis of OME from
methanol and formaldehyde was studied in detail. H3PO4/C catalysts have a comparable initial
OME yield and overall steady-state performance as benchmark zeolites.
As the acid loading of H3PO4/C catalysts can be changed independently of acid strength, it
could be demonstrated that the catalyst initial activity is not correlated with the acid loading
under the studied reaction conditions. This indicates that the reaction is running close to
equilibrium. This was supported by the investigation of sodium phosphate catalysts. The acid
strength of the monosodium phosphate (pKa = 7.21) was demonstrated to be too low to reach
reaction equilibrium. Accordingly, no reaction occurred over the disodium phosphate catalysts
(pKa = 12.32).
Two representative materials of H3PO4/C and zeolite catalyst families were compared in a
deactivation study. At a comparable acid site concentration, the H3PO4/C catalyst showed
superior stability over H-MOR-40 zeolite. It was argued that various factors including the
presence of mesopores in the matrix and the liquid state of the active phase may facilitate the
deactivation resistance of the H3PO4/C catalyst.
In this section, we highlighted the benefits of the long-known catalyst system of supported
phosphoric acid catalysts using activated carbon as a support. Although supported phosphoric
acid, typically supported on silica, has in many cases been replaced by zeolite catalysts in acid
catalysis, this work demonstrates a reaction in which the use of H3PO4 based catalyst may be
advantageous.
Two-step synthesis of OME from methanol 66
9 Two-step synthesis of OME from methanol
In this chapter, the implementation of a process combining methanol dehydrogenation and
OME synthesis will be presented. The aim is to show the gas-phase formation of OME from
methanol without intermediate reactant separation.
It was targeted to implement the combined process of methanol dehydrogenation and OME
synthesis as a proof of concept, hence not involving comprehensive studies or optimisation of
reaction conditions and catalysts.
For the above studied second reaction step, namely the formation of OME from methanol and
formaldehyde, the H-MOR-40 zeolite catalyst was employed. For the methanol
dehydrogenation step, the partial non-oxidative methanol dehydrogenation was assessed to be
more suitable than the oxidative route for two reasons. Both routes were introduced in chapter
2.4.1. Firstly, it is advantageous in terms of safety as there is no oxygen involved. In contrast
to oxidative methanol dehydrogenation, explosion limits do not need to be accounted for.
Secondly, the implementation and operation of the non-oxidative route in a laboratory-scale
test set-up is simpler. For example, an additional feed system of oxygen and water vapour is
not required as opposed to the oxidative process.
Table 9.1: Selection of reported catalyst systems for non-oxidative methanol dehydrogenation.
catalyst conversion /selectivity148 / %
stability148 reaction temperature
Na2CO3176
Na2CO3 + C 177
60 / 5750 / 90
stable after 10h ≥ 650 °C
Na-ZSM-5(B) 178, 179 63 / 92 98h at 550 °C 500 - 750 °C
Zn-13X 180 66 / 95 10% deactivationwithin 400 h 550 °C
ZnO/SiO2181
ZnO/SiO2182
75 / 7861 / 94
> 50h450 - 650°C
550 °C
A preliminary selection of catalyst classes to be studied in this section was made on the basis
of literature reports (see chapter 2.4.2). Two alkali- and two zinc-based catalysts were chosen
(see Table 9.1). Sodium carbonate is a non-volatile and cheap catalyst for non-oxidative
methanol dehydrogenation and is easily prepared. Its performance can potentially be improved
67 Two-step synthesis of OME from methanol
by addition of active carbon. Boron-substituted Na-ZSM-5 (Na-ZSM-5(B)) is a thermally
stable catalyst with a reported catalyst lifetime of 98h. Zn-13X and ZnO/SiO2 were also
selected owing to acceptable formaldehyde yield and long catalyst lifetime. Silver-based
catalysts were not included due to the reported recurring need for regeneration in the range of
a few hours.148 In case of copper-based catalyst, favourable catalyst performance and stability
was reported when co-feeding sulphur or selenium containing compound. This, however, adds
excessive complexity to the test set-up and may have adverse effects on the downstream
catalyst. Hence, these catalyst classes were not considered.
Typically, the non-oxidative methanol dehydrogenation is performed at atmospheric pressure,
which is favoured according to Le Chatelier’s principle. However, in the context of this
project the subsequent gas-phase OME formation needs to be taken into consideration. In
contrast to methanol dehydrogenation, increased reaction pressure is favourable.
In the following, the identification of appropriate reaction conditions with a focus on
preventing thermal formaldehyde decomposition is firstly discussed. In the following sections,
the screening of selected catalysts for methanol dehydrogenation and the implementation of
the combined process will be described. The experiments were carried out in a modified
reaction set-up including a reactor for methanol dehydrogenation (R1) and a reactor for OME
synthesis (R2) as indicated in chapter 4.2 and Figure 4.2. The reactor R1 is equipped with a
quartz inlet and can achieve reaction temperatures as high as 650 °C.
9.1 Thermal decomposition of formaldehyde
For non-oxidative MeOH dehydrogenation, a temperature range of 550-650 °C is required. In
this range, thermal formaldehyde decomposition is a relevant side reaction. Formaldehyde is
decomposed to carbon monoxide and hydrogen. In order to obtain meaningful data in the
catalyst screening, it is important to identify a set of reaction parameters at which thermal
decomposition is at a minimum.
For this purpose, the reactant mixture used for OME synthesis containing formaldehyde,
methanol and a minor amount of water, was used to quantify the extent of thermal
decomposition at varying residence times. Thermal decomposition tests were carried out at the
maximum temperature with a reactor filled with inert SiC material and quartz wool. As
permanent gases cannot be separated with the available gas chromatograph, the decomposition
products CO and H2 are not quantified.
Two-step synthesis of OME from methanol 68
When comparing reactant concentrations in the feed stream vs. reactor effluent (see Figure
9.1), it was observed that methanol is not affected. However, pronounced formaldehyde loss
occurs at conditions derived from OME synthesis screening conditions (τ1 in Figure 9.1).
Only 40% of formaldehyde is recovered after passing the reactor. An improvement can be
achieved by reducing the residence time of formaldehyde in the heated zone. The latter was
modified by changing gas-flows and pressure while keeping the reactant concentration
constant. The maximal gas flow in the set-up is limited to 400 ml/min. In case of pressure, a
compromise with OME synthesis needs to be made. At the lowest residence time that can be
implemented in the set-up, an acceptable level of 87% formaldehyde is recovered.
Figure 9.1: Study of thermal decomposition of formaldehyde. Share of initial formaldehyde (green) and methanol (grey) feedrecovered in dependence of residence time. Ratios of residence times τ1:τ2:τ3 of 1:4:8. Reaction conditions: τ1) 14 μL/minFA/MeOH solution, 100 ml/min inert gas, 10 bar; τ2) 56 μL/min FA/MeOH solution, 400 ml/min inert gas, 10 bar; τ3) 56μL/min FA/MeOH solution, 400 ml/min inert gas, 5 bar.
9.2 Catalyst screening
As mentioned above, four materials were selected for the preliminary screening of methanol
dehydrogenation catalysts. Sodium carbonate (Na2CO3) and boron containing Na-MFI zeolite
(Na-ZSM-5(B)) are members of the alkali-mediated catalyst class. In case of ZnO precipitated
on SiO2 (ZnO/SiO2) and Zn2+-ion-exchanged commercial faujasite zeolite 13X (Zn-13X), zinc
is the active component. The catalysts were prepared as specified in chapter 11.2.5. The
successful formation of crystalline phases was verified by powder X-ray diffraction (see
Figure 12.22 to Figure 12.25).
69 Two-step synthesis of OME from methanol
Figure 9.2: Initial conversion and selectivity of a) Na2CO3, b) Na-ZSM-5(B), c) Zn-13X and d) ZnO/SiO2 for non-oxidativemethanol dehydrogenation at 0.5g of 200-300 μm catalyst pellets in 1.5g SiC, 5 bars, 400 ml/min N2 flow, 28 μL/min MeOHfeed, p(MeOH): 0.18 bars. Reaction temperature is 650 °C for Na2CO3 and 550 °C for other catalysts.
For the screening of the selected catalysts, catalyst mass, reaction pressure and reactant
concentration were kept constant. However, different optimal temperature ranges are
recommended in literature. While 550 °C was specified for the majority of catalysts,178-180, 182
Na2CO3 requires a significantly higher reaction temperature of 650 °C and above.176 As the
identification of a suitable catalyst was the main objective of the preliminary screening, the
temperatures were adapted to the respective recommended ranges despite affecting the
Two-step synthesis of OME from methanol 70
comparability of results. It should be noted that selectivity is calculated with reference to
carbon converted. Hence, H2 and H2O are not considered.
The results of the catalyst screening are summarised in Figure 9.2. At first glance, it stands out
that the catalyst performance varies greatly.
For the Na2CO3 catalysts, 35% methanol conversion and formaldehyde selectivity of 55% is
determined. A marginal amount of methane is additionally formed. The residual methanol is
expected to be converted to carbon monoxide and coke deposits. While coke formation is
mentioned in literature,176 it is also clearly evident when comparing catalyst appearance before
and after catalytic testing. The initially white catalyst pellets turn black within two hours of
exposure to reactants (see Figure 9.3). This applies to all catalysts tested in the preliminary
screening.
Figure 9.3: Exemplary images of the quartz reactor inlet before (top) and after (bottom) methanol dehydrogenation testing.The catalyst bed is made up of initially white catalyst pellets and dark SiC granules. The section of the catalyst bed is markedwith blue lines.
The second alkali-based catalyst Na-ZSM-5(B) initially induces complete methanol
conversion to methane and other undetectable products. After 40 minutes reaction time, the
selectivity towards methane is, however suppressed. Instead, dimethyl ether as the major
detectable product and formaldehyde as a minor product are formed at decreasing methanol
conversion. Both Zn-based catalysts exhibit low selectivity towards detectable products. For
ZnO based catalysts, activity is claimed to be strongly correlated to surface area. Accordingly,
high surface area leads to MeOH decomposition only.183 Potentially, the performance of the
ZnO/SiO2 catalyst could be improved by adaptation of the preparation procedure towards low
surface area. However, this is not within the scope of the catalyst screening. Also in case of
Zn-13X, a distinct impact of initial zeolite composition and catalyst preparation procedure is
reported.148 It is interesting to note that the formaldehyde selectivity of Zn-13X increased
71 Two-step synthesis of OME from methanol
slowly but steadily until the end of the screening experiment. Potentially, improved
formaldehyde yield can be obtained at prolonged reaction times.
Although the optimal catalyst performance in terms of methanol conversion and formaldehyde
selectivity reported in literature, which amounts to >60% and 57-95% respectively, was not
reached in the preliminary screening, Na2CO3 could be identified as an adequate catalyst for
the proof of concept implementation of a methanol to OME process.
9.3 Combined process
With the selected catalyst sodium carbonate, a short study of reaction conditions limited to
pellet size and methanol partial pressure was conducted. Subsequently, the combined process
was tested with the derived reaction conditions.
Firstly, it was confirmed that catalyst performance is not significantly influenced by pellet
size. In a comparison of catalyst performance at two different sieve fractions, the same
formaldehyde yield of 20% was obtained. Nevertheless, conversion and selectivity varied to
some extent. At reaction conditions corresponding to the above described catalyst screening,
the 200-300 μm pellet size yielded 57% formaldehyde selectivity at 34% methanol conversion
and the 40-12 μm sieve fraction showed 76% formaldehyde selectivity at 25% methanol
conversion. In contrast, methanol partial pressure has a more pronounced impact on
formaldehyde yield. When the methanol partial pressure was increased, less formaldehyde is
formed while methanol conversion is affected only marginally (see Figure 9.4). A 3.5-fold
increase in methanol partial pressure resulted in a 40% decrease of FA selectivity and a 50%
decrease in FA yield. For the combination of both processes, the following reaction conditions
were chosen: 5 bar, 28 μL/min MeOH feed, 400 ml/min inert gas flow, p(MeOH): 0.18 bars,
reactor R1: 0.5g of 40-125 μm pellets of Na2CO3 in 1.5g SiC, 650 °C, reactor R2: 0.5g of 300-
400 μm pellets of H-MOR-40 in 3g SiC, 130 °C.
Two-step synthesis of OME from methanol 72
Figure 9.4: Initial conversion and selectivity of Na2CO3 as a function of methanol partial pressure. Reaction conditions: at0.5g of 40-125 μm catalyst pellets in 1.5g SiC, 5 bars, 400 ml/min N2 flow, 650 °C.
Figure 9.5: Initial conversion and selectivity for gas-phase OME formation from methanol. Reaction condition: 400 ml/minN2 flow, 28 μL/min MeOH feed, p(total): 5 bars, p(MeOH): 0.18 bars, reactor R1: 0.5g of 40-125 μm pellets of Na2CO3 in1.5g SiC, 650 °C, reactor R2: 0.5g of 300-400 μm pellets of H-MOR-40 in 3g SiC, 130 °C.
Indeed, in the respective test run OME1 was successfully formed from methanol at 60%
conversion and 75% selectivity (see Figure 9.5). Other detectable products include minor
73 Two-step synthesis of OME from methanol
amounts of formaldehyde and methyl formate. The formation of higher OME homologues is
hindered by the low partial pressure of reactants and low FA/MeOH ratio as discussed in
chapter 5.2 and 5.3. As mentioned above, this study was conducted as a proof of concept. A
range of approaches for improvement remain which include optimisation of catalyst
preparation, use of promotors (e.g. active carbon for Na2CO3 catalyst)184 and the more in-
depth study of reaction parameters, such as pressure, temperature, and residence time.
It is interesting to compare the above described results to the selective oxidation of methanol
to OME studied by various groups. The benchmark catalysts in methanol oxidation include
acid modified V2O5/TiO283 and FeMo based catalysts.185 OME1 yields of 46% and 50%,
respectively, have been reported for reactions in a fixed-bed reactor at atmospheric pressure.
In the above described combined process, a yield of 45% OME1 was achieved without further
optimisation of catalysts or reaction conditions.
Summary and final remarks 74
10 Summary and final remarks
In this thesis, the gas-phase synthesis OME from methanol and formaldehyde was
implemented and studied in detail. The design and assembly of a versatile set-up with high
safety standards allowed investigating reaction conditions and the catalytic activity of various
solid acids. With regards to reaction conditions, it was found that low reaction temperature,
high partial pressure of reactants and a high formaldehyde to methanol ratio are key factors
that favour OME yield, especially of OME>1 homologues. For the gas-phase process, this
repeatedly raised the necessity to make compromises. Both reaction temperature and reactant
partial pressure are limited by the saturation pressures of reactants and products. Favourable
conditions can more easily be catered to in a liquid-phase process, which accounts for the
higher yield of oligomeric OME in the liquid phase. Nevertheless, a suitable set of reaction
conditions for gas-phase testing could be identified.
On the basis of a screening of various catalyst classes, zeolites were identified as suitable
catalysts for an in-depth study of structure-activity relations. A general trend that could be
derived from the systematic study of zeolites is that in gas-phase synthesis of OME, zeolitic
materials with a low amount of acid sites show the best performance. The presence of strongly
acidic sites was linked to by-product formation. It could be demonstrated that weakly acidic
functional groups such as silanol groups are sufficient to catalyse OME formation. A
drawback of zeolite catalysts was found in limited catalyst lifetime. In the latter aspect,
supported phosphoric acid outperforms zeolites while exhibiting comparable conversion and
selectivity. From the study of phosphoric acid impregnated on activated carbon, some general
conclusion could be drawn. For example, it was suggested that for highly active catalysts with
low selectivity towards by-products, the reaction runs close to equilibrium. Over active
catalysts, the reaction occurred at such a high rate that non-equilibrium conditions could not
be realised within the experimental limits of reaction parameters. This impeded the additional
comparison of highly active catalysts at low conversion levels in order to get insight into
activity differences. The comparison of benchmark catalysts was hence based on the study of
catalyst deactivation and lifetime. Even at an acid site loading comparable to zeolites,
supported phosphoric acid has an increased lifetime.
In addition to zeolites and supported phosphoric acid, species that leach from ion-exchange
resins and from supported heteropoly acid were identified to be interesting, but difficult to
75 Summary and final remarks
study catalysts. The high yield in OME and the increased selectivity towards OME>1
oligomers may be a motivation for the future in-depth study of these catalyst systems.
Finally, the viability of the gas-phase synthesis of OME from methanol without separation of
intermediates was successfully demonstrated in this work. In future investigations, the
optimisation of the combined process with regards to both catalyst preparation and reaction
conditions may be of interest.
Experimental 76
11 Experimental
11.1 Commercial materials
11.1.1 Gases
All gases were purchased from Air Liquide, including helium (99,999%), argon (99.999%),
hydrogen (99,999%), synthetic air (20.5% O2 in N2), nitrogen (99.999%), calibrated carrier
gas containing 5%CH4/N2 and calibration gas containing 5% DME/N2.
11.1.2 Chemicals
The chemicals used in this work are summarised in Table 11.1. All chemicals were used as
supplied.
Table 11.1: Overview of employed chemicals including specifications and suppliers.
compound specifications supplier
1-butanol >99,8% VWR-International4,4’-trimethylenebis(N-methyl,N-benzyl-pipe-ridinium) dihydroxide
- Provided by Dr. Losch
ammonia 20% aqueous solution Rothboric acid > 99.5% Flukadisodium phosphate >99.0% Sigma Aldrichformic acid >95,0% Sigma Aldrichhydrogen peroxide 35% solution Sigma AldrichLudox AS-40 40% aqueous solution Sigma Aldrichmercaptopropyltrimethoxysilane >95,0% Sigma Aldrichmethanol 99,8% Sigma (Schüth)methyl formate >99,0% Sigma Aldrichmonosodium phosphate >99.0% Sigma Aldrichnitric acid 60% aqueous solution J.T. BakerOME1 99% Sigma AldrichOME3,4 - provided by Dr. Djinovicparaformaldehyde prilled Sigma Aldrichphosphoric acid 85% aqueous solution Alfa Aesarpotassium iodate >98% Sigma Aldrichpotassium iodide >99,0% Sigma Aldrichsilicotungstic acid >99,9% Sigma Aldrichsodium bicarbonate >99,0% Acros
77 Experimental
sodium nitrate >99,0% Sigma Aldrichsodium thiosulfate >98,0% Sigma Aldrichtetraethylorthosilicate >99,0% Sigma Aldrichtetra-n-propyl ammonium hydroxide 40% aqueous solution Sigma Aldrichtetrapropylammonium bromide 98% Sigma Aldrichtoluene >99,0% Sigma Aldrichtrioxane >99,0% Sigma Aldrichzinc nitrate hexahydrate >99,0% Sigma Aldrich
11.1.3 Catalysts and other solid materials
The zeolite catalysts were kindly supplied by Südchemie (now Clariant) and Degussa (now
Evonik Industries). The granular activated carbon TC303 was kindly supplied by Silcarbon
and sulphated zirconium hydroxide and tungstated zirconium hydroxide by MEL Chemicals.
Further materials were purchased by suppliers specified in Table 11.2.
Catalysts were activated as specified in chapter 11.3.1. All powdered catalysts were pressed
and sieved to 300-400 μm pellets after activation. The large crystals of Silicalite-1 were used
as synthesized. Carbon granules were sorted to 1-1.5 mm before use.
Table 11.2: Overview of commercial materials. For zeolite sample, the suffix denotes the SiO2/Al2O3-ratio.
entry material name /abbreviation
material type manufacturer
1 SO4-Zr(OH)4 sulphated zirconium hydroxide MEL chemicals
2WO3-Zr(OH)4 tungstated zirconium
hydroxideMEL chemicals
3PURALOXSCFa -140
γ-alumina Condea (now Sasol)
4Amberlyst 46 sulfonic acid functionalised
ion-exchange resinRohm and Haas
5Amberlyst 36 sulfonic acid functionalised
ion-exchange resinRohm and Haas
6 H-BEA-35 zeolite, Beta Südchemie (now Clariant)7 H-BEA-150 zeolite, Beta Südchemie (now Clariant)8 NH4-FAU-12 zeolite, Faujasite Alfa Aesar9 H-FAU-129 zeolite, Faujasite Degussa (now Evonik)10 H-FAU-340 zeolite, Faujasite Degussa (now Evonik)11 NH4-MOR-14 zeolite, Mordenite Südchemie (now Clariant)12 H-MOR-40 zeolite, Mordenite Südchemie (now Clariant)13 NH4-MFI-27 zeolite, Pentasil Südchemie (now Clariant)14 H-MFI-90 zeolite, Pentasil Südchemie (now Clariant)
Experimental 78
15 13X zeolite, Faujasite Alfa Aesar
16Aerosil 200 hydrophilic fumed silica,
amorphousEvonik
17 TC303 activated carbon granules Silcarbon
18 SiC silicon carbide Alfa Aesar
19 Quartz wool quartz Roth
11.2 Synthesis of catalysts
11.2.1 Supported silicotungstic acid
The supported heteropoly acid catalyst was prepared by impregnation of a commercial
γ-alumina support with an aqueous solution of silicotungstic acid. Briefly, 1g of H4[W12SiO40]
was dissolved in 3ml deionized water. 3g alumina support were slowly wetted with 1.3 ml
impregnation solution and mixed with a spatula. The resulting material was calcined at 200 °C
for 3h under static conditions.
11.2.2 SBA-15-SO3H
The first step, the preparation of thiol functionalised SBA-15 was performed according to
reference 186. Briefly, 1.5 g of SBA-15 was activated for 24 hours under argon in a round
bottom flask. Then, 30 ml of toluene was added and purged with argon for 30 minutes. 1.5 ml
of mercaptopropyltrimethoxysilane was added and refluxed for 24 hours. The solid was then
recovered by centrifugation and dried at 80 °C.
The thiol functionalised SBA-15 was further oxidised with H2O2. For that purpose, 1.3 g of
material was dispersed in 30ml of a 35% H2O2 solution. It was then centrifuged and
resuspended in 40ml of a 1 M H2SO4 solution. Finally, the product was recovered by
centrifugation and dried at 50 °C.
11.2.3 Silicalite-1
31 mL deionised water and 10.672 g tetrapropylammonium bromide were mixed in a 150 mL
Erlenmeyer flask equipped with a magnetic stirring bar. 23.2 mL Ludox AS-40 were
successively added and stirred at 750 rpm for 10 minutes at room temperature. Thereafter, the
synthesis mixture was cooled to 0 °C on an ice bath. 30 mL of a 20% aqueous solution of
ammonia were added to the synthesis mixture at 0 °C. The formed gel was aged for 2 h at 0 °C
while stirring at 750 rpm. The gel was then transferred into three 30 mL Teflon lined stainless
79 Experimental
steel autoclaves. The hydrothermal synthesis was performed in a preheated oven at 180 °C for
7 days. The final solid product was obtained in its pure form by centrifugation and washing
three times with deionised water, drying at 80 °C for 4 h and finally calcining at 550 °C under
static conditions for 7 h (2 °C/min). Large crystals with dimensions of approx. 42 x 8 μm as
determined with an optical microscope were obtained (Figure 12.26). The powder pattern is
presented in Figure 12.27 and nitrogen physisorption isotherms in Figure 12.28. In elemental
analysis, the aluminium content was below the detection limit of 50 ppm.
11.2.4 Supported phosphoric acid
1g of activated carbon granules was impregnated with 1.67 ml of aqueous solution,
corresponding to the filling of the support pore volume. The solution contained the active
component, H3PO4, NaH2PO4 or Na2HPO4, in varying concentrations, depending on the
targeted loading. The carbon granules were supplied in a centrifuge tube and the solution was
added dropwise with repeated shaking of the tube allowing homogeneous impregnation. The
impregnated samples are denoted x_H3PO4/C, the prefix x indicating the H3PO4 loading in [g
H3PO4 /g C]. Analogous nomenclature was used for NaH2PO4 and Na2HPO4 based sample. All
samples were dried at 130 °C overnight.
11.2.5 Methanol dehydrogenation catalysts
Sodium carbonate was prepared via calcination of sodium bicarbonate.177 Briefly, 6 g of
NaHCO3 were spread out in a crucible in a thin layer. The material was calcined in air under
static conditions at 250 °C for 90 minutes with a heating ramp of 2 °C/min. The resulting
powder was partially sieved to 40-125 μm and partially pressed and sieved to 200-300 μm
pellets.
The catalyst Na-ZSM-5(B) was synthesized following instructions from patent literature.179
62.5g of tetraethyl orthosilicate, 0.63g boric acid, 60g of a 20% aqueous solution of tetra-n-
propyl ammonium hydroxide and 5.1g sodium nitrate were mixed and transferred to an
autoclave. The autoclave was heated at 170°C for 72 h. The obtained powder was separated by
filtration and washed with deionised water. Subsequently, it was calcined in air at 450 °C for
8h with a heat ramp of 2 °C/min. Ion-exchange with sodium nitrate was performed at 100 °C
for 3h and repeated 5 times. Finally, the powder was washed with deionised water and dried at
150 °C.
Experimental 80
Zn-13X was prepared via ion-exchange of a commercial 13X zeolite.180 2g of 13X zeolite was
stirred in excess 1N zinc nitrate solution for 1h at 80 °C, then separated by filtration and
washed with deionised water. The exchange was repeated 10 times. The obtained powder was
dried at 110 °C for 3h and subsequently calcined 500 °C for 5h in static air.
The catalyst ZnO-SiO2 was prepared according to patent literature.181, 182 Briefly, 4.35 g of
zinc nitrate hexahydrate were dissolved in 100 ml deionised water mixed with 4.8 ml of a
60 wt% nitric acid solution. Then, 2.5g of tetraethyl orthosilicate were added. The mixture was
heated to 80 °C and stirred for 1h. The resulting solid was dried in a rotary evaporator and
calcined in a stream of air at 600 °C for 5h.
11.3 Modification procedures
11.3.1 Catalyst activation
Commercial zeolites in NH4-form were calcined at 550 °C. 1-2 g of sample were spread out in
a crucible and calcined at 550 °C for 5h with a ramp of 2 °C/min in static air.
H-MOR-40 samples were calcined at varying temperatures (350, 450, 550 °C). For that
purpose, 1 g of H-MOR-40 was prepared in a thin layer in a crucible and was calcined for 4 h
in static air with a heat ramp of 2 °C/min.
Sulphated and tungstated zirconia was obtained by calcination of the respective doped
zirconium hydroxide precursors in static air. The thermal treatment was performed at 550 °C
in case of sulphated and 750 °C in case of tungstated zirconium hydroxide as proposed by the
manufacturer. A heating ramp of 3 °C/min was applied and the final temperature was held for
3h.
The granular carbon support was activated by repeatedly adding hot deionised water (90-
95 °C), vigorously shaking and decanting the supernatant until the supernatant was clear.
Subsequently, the granules were dried at 80 °C until no change in mass was observed.
11.3.2 Sodium exchange of zeolites
For sodium exchange, 2 g of a NH4-form zeolite (NH4-MFI-27 or NH4-MOR-14) were
suspended in 20 mL of 1M NaNO3 solution and stirred for 1 h. This step was repeated twice.
The zeolite powder was then suspended in 20 mL of 1M NaNO3 solution and stirred
overnight. The zeolite was further washed with another aliquot of NaNO3 solution for 1 h. It
81 Experimental
was then separated by filtration, dried at 80 °C for 2 h and at 120 °C for 90 mins, then calcined
under static conditions at 550 °C for 5 h with a heating ramp of 1 °C/min.
11.3.3 Oxalic acid treatment of zeolites
For oxalic acid treatment of zeolites, 1.35 g of oxalic acid was dissolved in 30 ml deionised
water. 1.26 g of zeolite was slurried in oxalic acid solution overnight at room temperature. The
solid was then recovered by filtration and washed with deionised water. Subsequently, the
sample was dried at room temperature and calcined at 350 °C for 4h with a heating ramp of
2 °C/min.
11.3.4 Regeneration protocols
Silicalite-1 was regenerated by calcination under static air at 550 °C for 4 h with a heating rate
of 2 °C/min. H-MOR-40 was regenerated by thermal treatment at 350 °C (heating rate
1 °C/min) in a tube oven for 4 h under inert gas flow (50 mL/min Ar).
11.4 Characterisation methods
11.4.1 X-ray powder diffraction (PXRD)
PXRD data was either recorded in transmission or reflectance mode. Transmission PXRD data
was recorded with a Stoe STADI P transmission diffractometer in Debye–Scherrer geometry.
The device was equipped with a bent primary germanium monochromator for measurements
with monochromatic CuKα1 radiation and a position-sensitive detector made by Stoe.
Powdered samples were prepared in 0.5 mm borosilicate glass capillaries. Reflectance PXRD
data was measured on a Stoe STADI P diffractometer in Bragg-Brentano geometry with
CuKα1 radiation.
11.4.2 Temperature programmed desorption of ammonia (NH3-TPD)
NH3-TPD was performed on a Micromeritics Autochem II 2920 device. 80-100 mg of catalyst
were activated at 500 °C for 1h (heating ramp of 5 °C/min) and then cooled to 150 °C. The
sample was exposed to a flow of 5% NH3/He for 30 min and subsequently purged in He for
2 h. The desorption profile was collected in the range of 100 °C to 800 °C with a heating rate
of 10 °C min−1.
For the H-MOR-40 samples, a milder activation procedure was applied: 100 mg of catalyst
were activated at 350 °C for 5 h (heating ramp of 2 °C min−1) and then cooled to 150 °C.
Experimental 82
11.4.3 Pyridine adsorption followed by FTIR spectroscopy (Py-FTIR)
The acidity of selected samples was determined by adsorbing pyridine inside an FTIR
spectroscopy device (Py-FTIR). Self-supporting wafers (ca. 10 mg/cm2) were activated under
vacuum at 350 °C for 5 h. Then, pyridine (3 mbar) was adsorbed at 150 °C for 20 min.
Thereafter, desorption was carried out under high vacuum at 150 °C, 250 °C and 350 °C for
20 min at each temperature. Spectra were recorded using a Nicolet iS50 equipped with a MCT
detector. The absorption bands centred at 1545 cm-1 (PyH+) and 1455 cm-1 (PyL) were
selected for Brønsted and Lewis acid sites (BAS and LAS) quantification applying their
corresponding integrated molar extinction coefficients, εB=1.67 cm/μmol and
εL=2.22 cm/μmol, respectively.164
11.4.4 Magic-angle spinning nuclear magnetic resonance (MAS-NMR)
The solid-state 27Al MAS-NMR spectra were recorded on a Bruker Avance III HD 500WB
spectrometer using a double-bearing MAS probe (DVT BL4) at a resonance frequency of
130.3 MHz. The spectra were measured by applying single π/12-pulses (0.6 μs) with a recycle
delay of 1 s (6,000 scans) at two different spinning rates (10 kHz and 13 kHz). Prior to the
measurement the samples were saturated with water vapour in a desiccator overnight. The
spectra were referenced to external 1M aqueous solution of AlCl3.
31P MAS NMR spectra were recorded at a resonance frequency of 202.5 MHz. The spectra
were measured by applying single π/2-pulses (3.0 μs) with a recycle delay of 10 s (32 scans) at
a spinning rate of 10 kHz. High-power proton decoupling (spinal64) was applied. Prior to the
measurements the samples were dried at 130 °C for 12 h. The spectra were referenced with
respect to 85% aqueous H3PO4 using solid NH4H2PO4 as secondary reference (δ = 0.81 ppm).
11.4.5 Thermogravimetric analysis coupled with mass spectrometry (TG-MS)
Thermogravimetric analysis (TG) was performed using a NETZSCH STA 449 F3 Jupiter
thermal analysis device. For the determination of ash and water content in carbons,
approximately 3 mg of sample were heated in a stream of 40 mL/min synthetic air with an
additional protective flow of 20 mL/min of argon at a heating rate of 10 °C/min. Data was
collected in the range of 45 - 1000 °C.
In case of zeolite catalysts, the TG method was coupled with mass spectrometry (TG-MS)
using a NETZSCH QMS 403 D Aëolos mass spectrometer. Approximately 5 mg of sample
83 Experimental
were heated in 40 mL/min gas flow (argon or synthetic air) with an additional protective flow
of 20 mL/min of argon. The ramp rate was 10 °C/min in a temperature range of 40 - 900 °C.
Mass spectra were collected in scan mode or in multiple ion detection (MID) mode.
11.4.6 Diffuse reflectance infrared spectroscopy (DRIFTS)
The samples were activated under inert gas flow at 235 °C in a DRIFT cell. For adsorption of
probe molecules, an inert carrier gas flow was bubbled through a probe liquid at room
temperature (reactant mixture 60% FA, 38% MeOH, 2% H2O or neat MeOH or OME1) before
entering the DRIFTS-chamber tempered at 40 °C. The chamber was subsequently purged with
inert gas. All spectra were collected at 40 °C with a Nicolet Magna-IR 560 spectrometer.
11.4.7 Nitrogen physisorption
Nitrogen physisorption was studied using a Micromeritics 3 Flex device. Samples were
activated under vacuum at 250 °C for 8 h in a Smart VacPrep unit. Adsorption and desorption
isotherms were measured at 77.4 K. Data evaluation was performed using the MicroActive
software package by Micromeritics. The total pore volume was determined at p/p0 = 0.95.
11.4.8 GC-MS
For GC-MS measurements, a sample was separated using a Thermofisher Trace-GC Ultra
device equipped with a DB-WAXETR column and was subsequently analysed using a
Thermofisher ISQ mass spectrometer with EI-ionization method.
11.4.9 Scanning electron microscopy (SEM)
SEM micrographs of zeolite samples were measured on a Hitachi S-3500N scanning electron
microscope with 15kV acceleration voltage.
11.4.10 Energy dispersive X-ray spectroscopy (EDX)
SEM-EDX measurements of supported phosphoric acid catalysts were carried out on a Hitachi
S-5500 equipped with a Thermo Scientific NORAN System 7 X-ray Microanalysis System
and a Thermo Scientific UltraDry EDS Detector 30mm2 silicon drift detector. Experiments
were carried out at an acceleration voltage of 30 kV. Cross sections of catalyst granules were
prepared using a Hitachi Ion Milling System E-3500. For this purpose, catalyst granules were
fixed to an aluminium support with graphite based adhesive and milled with argon ions for
12h at 6 kV and 100μA ion current.
Experimental 84
11.4.11 Transmission electron microscopy (TEM)
TEM micrographs of zeolite samples were collected on a Hitachi H-7100 microscope with
100kV acceleration voltage. The samples were physically applied to lacey carbon coated
copper grids.
11.4.12 Elemental analysis
Elemental analysis was performed via absorption spectroscopy at the external service provider
Mikroanalytisches Laboratorium Kolbe in Mülheim a.d. Ruhr.
11.5 Batch reactions
Batch reactions were carried out in a 100 ml stainless steel autoclave at 100 °C for 24 h.
Firstly, 9 g solid trioxane, 1.2 g Amberlyst 46 and a stirring bar were filled into the autoclave.
The latter was sealed and 17.7 ml of OME1 were introduced with a syringe via a ball valve.
The autoclave was then introduced into a heating block preheated to 100 °C. After 24 h, the
reactor was cooled down to room temperature. Samples were taken using a syringe equipped
with a filter.
11.6 Wet-chemical analysis methods
11.6.1 Preparation of methanolic formaldehyde solution
The reactant solution for evaporation in the test set-up was prepared by dissolution of
paraformaldehyde in methanol. Briefly, 120 g paraformaldehyde and 80 g methanol were
mixed in a round bottom flask and refluxed at 80 °C for 24h. Then, the mixture was cooled to
room temperature and filtered.
11.6.2 Iodometry
The formaldehyde content of methanolic formaldehyde solutions was determined via
iodometry. Firstly, a 0.1M thiosulfate (Na2S2O3) reference solution was prepared. For
calibration, a weighted amount of potassium iodate and excess potassium iodide were
dissolved and acidified. Iodine that formed according to equation (11-1) was titrated with
0.1M Na2S2O3 solution, which allowed calculating the exact Na2S2O3 content according to
equation (11-2). Secondly, a 0.05 M iodine solution was prepared by dissolution of iodine and
excess potassium iodide. Its concentration was determined with 0.1M Na2S2O3 solution
following equation (11-2).
85 Experimental
+ 5 + 6 3 + 6 + 3 (11-1)
+ 2 → 2 + (11-2)
+ + 3 + 2 + 2 (11-3)
Formaldehyde analysis was carried out by mixing an aliquot of sample with a known amount
of iodine solution and an aqueous solution of sodium hydroxide. The mixture was allowed to
react according to equation (11-3) for 15 minutes. Then, the solution was acidified with
sulphuric acid and the residual iodine was titrated with 0.1M Na2S2O3 according to equation
(11-2).
11.6.3 Karl-Fischer titration
Water content of methanolic formaldehyde solutions was determined via Karl-Fischer
titration. A Metrohm 831 KF Coulometer equipped with a Metrohm 728 Stirrer was used for
this purpose. Hydranal Coulomar AK and CG-K titration solutions from Honeywell-Fluka,
which are suitable for analysis of ketones and aldehydes, were employed.
Appendix 86
12 Appendix
Figure 12.1: Initial selectivity and conversion of catalysts determined in the interval of 40 - 70 min. reaction time. Reactionconditions: 10 bar, 130 °C, 0.5 g of H-MOR-40, 100 mL/min inert gas flow, 14 μL/min FA/MeOH solution feed, water feedvaried. Weight hourly space velocity (WHSV) for formaldehyde: 1.1 g(FA)*g(cat)-1*h-1.
Figure 12.2: : Study of reproducibility. Initial selectivity and conversion of H-MOR-40 determined in the interval of 40 - 70min. reaction time. Reaction conditions: 10 bar, 130 °C, 0.5 g of catalyst, 100 mL/min inert gas flow, 14 μL/min FA/MeOHsolution feed. WHSVFA: 1.1 g(FA)*g(cat) 1*h-1.
87 Appendix
Figure 12.3: NH3-TPD profiles of H-BEA-35 and H-BEA-150.
Figure 12.4: NH3-TPD profiles of H-FAU-12, H-FAU-129 and H-FAU-340.
Appendix 88
Figure 12.5: NH3-TPD profile of H-MFI-27, H-MFI-90, Silicalite-1 and Aerosil 200.
Figure 12.6: NH3-TPD profile of H-MOR-14 and H-MOR-40.
89 Appendix
Figure 12.7: FTIR spectra of the H-MOR-40 at different calcination temperatures after activation by outgassing at 350 °C: a)ν(OH) vibrations and b) stretching vibration region of the pyridine interacting with the acid sites before adsorption (BA) andafter 20 min desorption at 150 °C, 250 °C and 350 °C.
In order to get more information about the influence of calcination temperature on the
distribution of Brønsted and Lewis acid sites (BAS and LAS, respectively), a pyridine
adsorption study was performed. Figure 12.7 presents the transmission spectra of H-MOR-40
calcined at 350 °C, 450 °C and 550 °C. In the OH stretching vibration region (Figure 12.7a),
five different absorption bands are observed in the spectra before adsorption (BA):187, 188 a)
3745 cm-1: characteristic band of terminal silanols, b) 3732 cm-1: corresponds to silanols
located at internal positions (internal defects), c) 3701 and 3659 cm-1: usually associated to
OH groups located on extra-framework species and d) 3609 cm-1: ascribed to bridging acidic
hydroxyl groups (Si-OH-Al). After adsorption of pyridine at 150 °C, the latter bands fade
away giving rise to the appearance of new bands in the pyridine vibration region (Figure
12.7b). The pyridine interaction with the protons of Brønsted sites leads to typical bands at
1636 and 1545 cm-1 characteristic of pyridinium ions (PyH+).162, 189 On the other hand,
pyridine adsorbed on Lewis acid sites (PyL) is responsible for the band at 1455 cm-1,
corresponding to the 19b vibration mode of the pyridine. Furthermore, analysing the 8a
4000 3800 3600 3400
370137
45
3659
H-MOR-40_550°C
3609
Wavenumber (cm-1)
0.537
32
BA
150 °C
250 °C
350 °C
1650 1575 1500 1425 135014
61
350 °C16
111636 16
21
Abs
orba
nce
(a. u
.)
0.2
1545 1455
150 °C
250 °C
4000 3800 3600 3400
3659
H-MOR-40_450°C
3609
Wavenumber (cm-1)
0.5
BA
150 °C
250 °C
350 °C
3745 37
3237
01
1650 1575 1500 1425 1350
1461
350 °C
161116
36 1621
Abs
orba
nce
(a. u
.)
0.2
1545
1455
150 °C
250 °C
4000 3800 3600 3400
3665
H-MOR-40_350°C
3609
Wavenumber (cm-1)
0.5
BA
150 °C
250 °C
350 °C
3745 37
3237
01
1650 1575 1500 1425 1350
1461
350 °C
161116
3616
21
Abs
orba
nce
(a. u
.)0.2
1545
1455
150 °C
250 °C
a) b)
a) b)
a) b)
Appendix 90
vibration mode region is possible to distinguish two different Lewis species at 1621 and 1611
cm-1, which can be ascribed to the presence of unsaturated Al3+ ions with different
environments.190 In Figure 12.7b), a decrease of the band intensities with the temperature due
to the existence of acid sites with different strengths is also observed. Besides, the formation
of a new band at 1461 cm-1 is associated to iminium ions interacting with some PyL
complexes.187 Apparently, the existence of this band depends on calcination temperature and,
hence, the presence of acidic protons (CBAS, H-MOR-40_350°C > CBAS, H-MOR-40_450°C > CBAS, H-MOR-
40_550°C). This fact explains why this band is sharper for the sample calcined at 350 °C
(possessing higher initial concentration of BAS and more probabilities that some iminium ions
interact with the PyL) than at 450 °C or 550 °C.
Figure 12.8: NH3-TPD profiles of H-MOR-40 treated at varying calcination temperatures. In order to not subject the samplesto change in EFAl-content, a mild activation procedure was chosen: 100 mg of catalyst were activated at 623 K for 5 h(heating ramp of 2 K min−1) and then cooled to 423 K.
91 Appendix
Figure 12.9: Exemplary SEM micrograph of commercial H-FAU-12 zeolite
Figure 12.10: Exemplary particle size histogram of commercial H-FAU-12 including 300 particles measured.
Appendix 92
Figure 12.11: Conversion as a function of external surface area.
Figure 12.12: TG-MS curve of Silicalite-1 measured in synthetic air.
93 Appendix
Figure 12.13: TG-MS curve of H-MOR-40 measured in synthetic air.
Figure 12.14: TG-MS curve of H-MOR-40 measured in argon.
Appendix 94
Figure 12.15: Right: Initial conversion/selectivity determined in the interval of 1-3 h reaction time of fresh samples and ofregenerated samples. Reaction conditions: 10 bar, 130 °C, 0.5 g of catalyst, 100 mL/min inert gas flow, 14 μL/min FA/MeOHsolution feed WHSV for formaldehyde: 1.1 g(FA)/g(cat)-1*h-1.
Figure 12.16: DRIFT-FTIR-spectra of activated Aerosil 200 before and after adsorption of probe molecules.
95 Appendix
Figure 12.17: DRIFT-FTIR-spectra of activated Silicalite-1 before and after adsorption of probe molecules.
Figure 12.18: TG-MS curve of granular carbon support measured in air after activation according to chapter 11.3.1.
Appendix 96
Figure 12.19: Relation of 31P MAS NMR signal per catalyst weigth and the mass of phosphoric acid loaded onto the granularcarbon via incipenet wetness impregnation.
Figure 12.20: 31P MAS NMR of Na2HPO4 with varying scan repeating times of 30s, 60s, 120s, 600s and 8h. Full relaxation of31P nucleus is only achieved after >>600s.
97 Appendix
Figure 12.21: Share of feed mass flow exiting the reactor as a function of time for granular carbon support. Reactionconditions: 500 mg sample, 10 bar, 130 °C, 100 ml/min inert gas flow, 14 uL/min FA/MeOH mixture. WHSV forformaldehyde of 1.1 g(FA)/g(cat)-1*h-1.
Figure 12.22: Powder pattern of Na-ZSM-5(B).
Appendix 98
Figure 12.23: Powder patterns of commercial 13X zeolite and Zn-ion-exchanged 13X zeolite.
Figure 12.24: Powder pattern of ZnO-SiO2 catalyst and reference reflections of ZnO wurzite (PDF number 89-0511).
99 Appendix
Figure 12.25 Powder pattern of Na2CO3 catalyst.
Figure 12.26: Light microscope image of Silicalite-1 crystals.
Appendix 100
Figure 12.27: Powder patterns of Silicalite-1: a) experimental and b) calculated using cif-file from http://www.iza-structure.org/databases/ accessed on 22.02.2018.
Figure 12.28: N2-physisorption isotherm of Silicalite-1 crystals. Step and hysteresis of isotherm in the range of p/po= 0.1 - 0.2is related to a phase transition of adsorbate molecules inside the micropores as described by Müller and Unger.191
101 References to laboratory journal entries
13 References to laboratory journal entries
Table 13.1: References to laboratory journal entries for commercial and synthesised materials.
material sample-ID material sample-ID
H-FAU-12 GRC-GB-011-15 H-MOR-40_550 GRC-GB-011-52H-FAU-129 GRC-GB-011-10 0.9_H3PO4/C GRC-GB-053-04H-FAU-340 GRC-GB-011-09 0.6_H3PO4/C GRC-GB-053-06H-BEA-35 GRC-GB-011-07 0.3_H3PO4/C GRC-GB-053-07H-BEA-150 GRC-GB-011-13 0.04_H3PO4/C GRC-GB-053-11H.MOR-14 GRC-GB-028-01 H3PO4/C (0.7mmol) GRC-GB-053-17H-MOR-40 GRC-GB-011-03 NaH2PO4/C (0.7mmol) GRC-GB-053-18H-MFI-27 GRC-GB-013-01 Na2HPO4/C (0.7mmol) GRC-GB-053-19H-MFI-90 GRC-GB-011-12 0.08_NaH2PO4/C GRC-GB-053-18Silicalite-1 GRC-GB-037-01 0.3_NaH2PO4/C GRC-GB-053-12SO4-ZrO2 GRC-GB-019-01 Na2CO3 GRC-GB-058-01WO3-ZrO2 GRC-GB-019-02 Na-ZSM-5(B) GRC-GB-049-01HPA/Al2O3 GRC-GB-012-01 Zn-13X GRC-GB-050-01Amberlyst 36 GRC-GB-011-66 ZnO/SiO2 GRC-GB-057-03Na-MFI-27 GRC-GB-044-04 SBA-15-SO3H JOI-JA-147Na-MOR-14 GRC-GB-044-03 Aerosil GRC-GB-011-17H-MOR-40_350 GRC-GB-011-53 Carbon support GRC-GB-011-61H-MOR-40_450 GRC-GB-011-51
Table 13.2: References to laboratory journal entries for catalytic tests.
figure description sample-ID
Figure 5.1 temperature dependence GRC-GB-031-04 (H-MOR-40)GRC-GB-031-14 (H-MOR-40)GRC-GB-031-91 (Silicalite-1)GRC-GB-062-15 (Silicalite-1)
Figure 5.2 reversibility GRC-GB-031-74 (MeFO Feed)GRC-GB-031-76 (OME1 + H2O feed)
Figure 5.3 partial pressure
reactant ratio
GRC-GB-031-09GRC-GB-031-31GRC-GB-031-38GRC-GB-031-09GRC-GB-031-10GRC-GB-031-11
References to laboratory journal entries 102
Figure 6.1 preliminary catalyst screening GRC-GB-027-01 (H-MOR-40)GRC-GB-027-02 (H-FAU-5)GRC-GB-027-04 (SO4-ZrO2)GRC-GB-027-05 (WO3-ZrO2)GRC-GB-027-06 (HPA/Al2O3)GRC-GB-027-07 (HPA residual)GRC-GB-025-01 (Amberlyst)
Figure 7.1 zeolite catalyst screening GRC-GB-031-32 (H-FAU-12)GRC-GB-031-19 (H-FAU-129)GRC-GB-031-16 (H-FAU-340)GRC-GB-030-02 (H-BEA-35)GRC-GB-031-08 (H-BEA-150)GRC-GB-031-27 (H-MOR-14)GRC-GB-030-03 (H-MOR-40)GRC-GB-027-03 (H-MFI-27)GRC-GB-031-08 (H-MFI-90)GRC-GB-031-56 (Silicalite-1)
Figure 7.2 conversion and yield as afunction of total ammoniadesorbed
See Figure 7.1, additionally:GRC-GB-043-28 (H-MOR-40_350)GRC-GB-043-26 (H-MOR-40_450)GRC-GB-043-27 (H-MOR-40_550)GRC-GB-031-42 (Aerosil)
Figure 7.4 sodium exchanged zeolite GRC-GB-043-15 (Na-MOR-14)GRC-GB-043-16 (Na-MFI-27)
Figure 7.6 H-MOR-40 calcination See Figure 7.1 and Figure 7.2Figure 7.7 OME yield as a function of
surface areaSee Figure 7.1
Figure 7.8 adapted reaction conditions GRC-GB-031-82 (H-MOR-40)GRC-GB-031-84 (Silicalite-1)
Figure 7.9 deactivation curve GRC-GB-031-89 (H-MOR-40)GRC-GB-031-93 (Silicalite-1)
Figure 8.5 H3PO4/C loading
H3PO4/C WHSV
GRC-GB-043-59 (0.9_ H3PO4/C)GRC-GB-043-84 (0.3_ H3PO4/C)GRC-GB-043-88 (0.04_ H3PO4/C)GRC-GB-043-99 (WHSV = 1.1, granules)GRC-GB-043-79 (WHSV = 42.7, granules)GRC-GB-043-80 (WHSV = 42.7, powder)
Figure 8.6 Ssdium phosphates
NaH2PO4/C loading
GRC-GB-043-94 (H3PO4/C)GRC-GB-043-91 (NaH2PO4/C)GRC-GB-043-93 (Na2HPO4/C)GRC-GB-043-91 (0.08_NaH2PO4/C)GRC-GB-043-82 (0.3_NaH2PO4/C)
103 References to laboratory journal entries
Figure 8.7 deactivation curve GRC-GB-043-98 (H-MOR-40)GRC-GB-043-99 (H3PO4/C)
Figure 9.1 thermal decomposition of FA GRC-GB-062-03Figure 9.2 methanol dehydrogenation
catalyst screeningGRC-GB-062-07 (Na2CO3)GRC-GB-062-11 (Na-ZSM-5(B))GRC-GB-062-12 (Zn-13X)GRC-GB-062-13 (ZnO/SiO2)
Figure 9.4 methanol partial pressure GRC-GB-062-04Figure 9.5 OME formation from MeOH GRC-GB-062-08Figure 12.1 water content GRC-GB-043-37
GRC-GB-043-38GRC-GB-043-39
Figure 12.2 reproducibility GRC-GB-027-01GRC-GB-030-03GRC-GB-031-14GRC-GB-031-30GRC-GB-031-25
Figure 12.11 conversion as a function ofexternal surface area
See Figure 7.1
Figure 12.15 regeneration GRC-GB-043-23 (H-MOR-40)GRC-GB-043-24 (H-MOR-40, 1. regeneration)GRC-GB-043-25 (H-MOR-40, 2. regeneration)GRC-GB-031-91 (Silicalite-1)GRC-GB-043-03 (Silicalite-1, 1. regeneration)GRC-GB-043-05 (Silicalite-1, 2. regeneration)
Figure 12.21 granular carbon support GRC-GB-043-52
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