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Publications Publications

Publications

  • 2017
  • A. More and G. Veser, “Physically mixed carriers for syngas production via chemical looping dry reforming”, AIChE Journal 63 (2017) 51–59.  doi:10.1002/aic.15380
  • H Chi, CS Bonifacio, CM Andolina, EA Stach, G Veser, JC Yang, "Structural Change of a Cu/ZnO Catalyst under Methanol Observed by ETEM", Microscopy and Microanalysis 23 (S1) (2017) 2100-2101.  doi:10.1017/S1431927617011163
  • A. More, Ch. Hansen, and G. Veser, "Production of inherently separated syngas streams via chemical looping methane cracking", Catal. Today 298 (2017) 21-32.  doi:10.1016/j.cattod.2017.07.008
  • 2016
  • S. Bhavsar, N. Isenberg, A. More, and G. Veser, “Lanthana-Doped Ceria as Active Support for Oxygen Carriers in Chemical Looping Combustion”, Applied Energy 168 (2016) 236–247.  doi:10.1016/j.apenergy.2016.01.073
  • Y. Lai and G. Veser, “Zn-HZSM5 Catalysts for Methane Dehyroaromatization”, Environmental Progress Sustainable Energy 35 (2016) 334–344. DOI:10.1002/ep.12322
  • S. Mahoney, M. Najera, Q. Bai, E. A. Burton, and G. Veser, ”The developmental toxicity of complex silica-embedded nickel nanoparticles is determined by their physicochemical properties”, PLoS ONE 11(3) (2016): e0152010.  DOI: 10.1371/journal.pone.0152010
  • Ch. S. Ewing, G. Veser, J. J. McCarthy, D. S. Lambrecht, and J. K. Johnson, “Predicting Catalyst-Support Interactions between Metal Nanoparticles and Amorphous Silica Supports”, Surface Science 652 (2016) 278–285.  doi:10.1016/j.susc.2016.03.004.
  • A. More, S. Bhavsar, and G. Veser. “CO2 Activation Via Chemical Looping Dry Reforming Of Methane”, Energy Technology 4 (2016) 1147–1157.  DOI:10.1002/ente.201500539
  • G. Veser and Ch. Müller, “Chemical Looping for Energy Technology: A Special Issue”, Energy Technol. 4 (2016) 1127–1129. DOI: 10.1002/ente.201600593
  • Y. Lai and G. Veser, “The Nature of the Selective Species in Fe-HZSM5 for Non-Oxidative Methane Dehydroaromatization”, Catal. Sci. Technol. 6 (2016) 5440-5452. DOI:10.1039/C5CY02258D
  • Ch. S. Ewing, A. Bagusetty, E. G. Patriarca, D. S. Lambrecht, G. Veser, and J. K. Johnson, “Impact of Support Interactions for Single-site Molybdenum Catalysts on Amorphous Silica”, Ind. Eng. Chem. Res. 55 (2016) 12350–12357.  doi: 10.1021/acs.iecr.6b03558
  • 2015
  • Ch. S. Ewing, M. J. Hartmann, K. R. Martin, A. M. Musto, S. J. Padinjarekutt, E. M. Weiss, G. Veser, J. J. McCarthy , J. K. Johnson, and D. S. Lambrecht. “Structural and Electronic Properties of Pt13 Nanoclusters on Amorphous Silica Supports”, J. Phys. Chem. C 119 (2015) 2503–2512
  • Y. Lai, M. N. Rutigliano, and G. Veser, “Controlled Embedding of Metal Oxide Nanoparticles in ZSM-5 Zeolites through Pre-encapsulation and Timed Release”, Langmuir 31 (2015) 10562-10572
  • Ch. S. Ewing, G. Veser, J. J. McCarthy , J. K. Johnson, and D. S. Lambrecht. “Effect of Support Preparation and Nanoparticle Size on Catalyst–Support Interactions between Pt and Amorphous Silica”, J. Phys. Chem. C 119 (2015) 19934-19940.
  • 2014
  • G. Veser, “Shale Gas Technology: A Special Issue”, Energy Technol. 2 (2014) 943 – 945.
  • S. Bhavsar and G. Veser, "Chemical looping beyond combustion: production of synthesis gas via chemical looping partial oxidation of methane”, RSC Advances 4 (2014) 47254-47267.
  • D. W. Palm, R. M. Enick, and G. Veser, "Nano-confined Amine-functionalized Silicone Oil Sorbents for Rapid CO2-Capture”, Ind. Eng. Chem. Res. 53 (2014) 16476-16484.
  • S. Bhavsar, B. Tackett, and G. Veser, "Evaluation of Iron- and Manganese-based Mono- and Mixed-Metallic Oxygen Carriers for Chemical Looping Combustion”, Fuel 136 (2014) 268–279.
  • Ch. S. Ewing, S. Bhavsar, G. Veser, J. J. McCarthy, and J. K. Johnson, "Accurate Amorphous Silica Surface Models from First Principles Thermodynamics of Surface Dehydroxylation”, Langmuir 30 (2014) 5133–5141.
  • S. Bhavsar, M. Najera, R. Solunke, and G. Veser, "Chemical Looping: To Combustion and Beyond!”, Catalysis Today, 228 (2014) 96–105.
  • S. Bhavsar, M. Najera, A. More, and G. Veser, "Chemical Looping Processes for Fuel-Flexible Combustion and Fuel Production”, in: “Reactor and Process Design in Sustainable Energy Technology”, F. Shi (editor), Elsevier, 2014 (invited chapter).
  • 2013
  • S. Bhavsar and G. Veser, “Bimetallic Fe-Ni Oxygen Carriers for Chemical Looping Combustion”, Ind. Eng. Chem. Res.,52 (2013) 15342–15352.
  • S. Bhavsar and G. Veser, “Reducible Supports for Ni-based Oxygen Carriers in Chemical Looping Combustion”, Energy Fuels 27 (2013) 2073–2084.
  • 2012
  • S. Liang and G. Veser, “Mixed lanthana/ceria nanorod-supported gold catalysts for water-gas-shift”, Catal. Lett. 8 (2012) 936-945.
  • S. Bhavsar, M. Najera, and G. Veser, “Chemical Looping Dry Reforming as Novel, Intensified Process for CO2 Activation”, Chem. Eng. Technol. 35 (2012) 1281–1290.
  • W. Zou, W. Liu, L. Luo, S. Zhang, R. Lu, and G. Veser, “Detection of nitro explosives via LSPR sensitive silver clusters embedded in porous silica”, J. Mater. Chem. 22 (2012) 12474-12478.
  • 2011
  • S. Liang and G. Veser, “Nanocatalysts for the Water-Gas-Shift Reaction”, Nanomaterials & Energy 1 (2011) 117-135.
  • M. Najera, R. Solunke, T. Gardner, and G. Veser, “Carbon capture and utilization via chemical looping dry reforming”, Chem. Eng. Res. & Des. 89 (2011) 1533-1543 (invited paper for special edition on carbon capture and sequestration).
  • S. Liang, Y. Wang, A. Cao, and G. Veser, “Highly stable, mesoporous mixed lanthanum-cerium oxides with tailored structure and reducibility”, J. Mater. Sci. 46 (2011) 2928-2937.
  • R. Solunke and G. Veser, “Integrating desulfurization with CO2 capture in chemical looping combustion”, Fuel 90 (2011) 608-617.
  • 2010
  • A. Cao, R. Lu, and G. Veser, “Stabilizing Metal Nanoparticles for Heterogeneous Catalysis”. Phys. Chem. Chem. Phys., 12 (2010) 13499 - 13510 (invited perspectives paper).
  • R. Solunke and G.Veser, “Hydrogen production via Chemical-looping in a fixed bed reactor”, Ind. Eng. Chem. Res. 49 (2010) 11037–11044.
  • G. Veser, “Multiscale Process Intensification for Catalytic Fuel Processing: From Nanostructured Catalysts to Integrated Reactor Concepts”, Catal. Today, 157 (2010), 24-32.
  • Y. Wang, S. Liang, A. Cao, R. L. Thompson, and G. Veser, “Au-mixed lanthanum/cerium oxide catalysts for water-gas-shift’, Appl. Catal. B, 99 (2010), 89-95
  • A. Cao and G. Veser, “Exceptional high-temperature stability through “distillative” self-stabilization in bimetallic nanoparticles”, Nature Materials 9 (2010), 75-81.
  • 2009-2005
  • T. Liu, H. Temur, and G. Veser, “Autothermal Reforming of Methane in a Reverse-Flow Reactor”, Chem. Eng. Technol. 32 (2009), 1358-1366.
  • R. Solunke, and G. Veser, “Nanocomposite Oxygen Carriers for Chemical Looping Combustion of Sulfur-Contaminated Synthesis Gas”, Energy Fuels 23 (2009), 4787-4796.
  • T. Sanders, Ph. Pappas, and G. Veser, “Supported nanocomposite catalysts for high-temperature partial oxidation of methane”, Chem. Eng. J., 142 (2008),122-132. 
  • H. Tian, K. Chaudhari, Th. Simonyi, R. Siriwardane, J. Poston, T. Liu, T. Sanders, and G. Veser, “Chemical Looping Combustion of Coal Derived Synthesis Gas over Copper Oxide Oxygen Carriers”, Energy Fuels, 22 (2008), 3744–3755.
  • G. Veser, “Short Contact-Time Reactors”, Chapter 10.5 in: “Handbook of Heterogeneous Catalysis” (G. Ertl, H. Knözinger, F. Schüth, and J. Weitkamp, Eds), 2nd edition, VCH-Wiley, 2008 (invited chapter)
  •  T. Liu, C. Snyder, and G. Veser, “Catalytic Partial Oxidation of Methane: Is a Distinction between Direct and Indirect Reaction Mechanism Meaningful?”, Ind. Eng. Chem. Res., 46 (2007), 9045-9052.
  • S, Chattophadyay and G. Veser, "Heterogeneous-Homogeneous Interactions in Catalytic Microchannel Reactors", AIChE Journal, 52 (2006) 2217-2229.
  • T. Sanders and G. Veser, "Supported Nanocomposite Catalysts for High-Temperature Methane Conversion", ACS Fuel Chemistry Preprints 51 (1) (2006).
  • T. Liu, T. Symosi, R. Siriwardane, and G. Veser, "Nanocomposite Oxygen Carriers for Chemical Looping Combustion", ACS Fuel Chemistry Preprints 51 (2) (2006).
  • T. Liu, V. Gepert, and G. Veser, "Process Intensification through Heat Integration for High-Temperature Millisecond Contact-Time Catalysis", Chem. Eng. Res. Design, 83 (2005) 611 - 618.
  • M. Kirchhoff, U. Specht, and G. Veser, "Engineering High-Temperature Stable Nanocomposite Materials", Nanotechnology, 16 (2005) S401-408.
  • G. Veser, "Process Intensification through Heat-Integration For High-Temperature Catalysis", Chapter 9 in: "Microreaction Technology and Process Intensification" (Y. Wang and J.D. Holladay, Eds.), ACS Symposium Series No. 914, Washington, 2005.
  • G. Veser, "Combined Reactor and Catalyst Engineering for Efficient Decentralized Conversion of Methane to Synthesis Gas or Hydrogen", STREM Chemiker 22 (2005) 24-29.
  • D. Neumann and G. Veser, "Catalytic Partial Oxidation of Methane in a Reverse-Flow Reactor", AIChE Journal, 51 (2005) 210-223.
  • T. Liu, C. Snyder, and G. Veser, "Catalytic Partial Oxidation of Methane: Is a Distinction between Direct and Indirect Reaction Mechanisms Meaningful?", ACS Fuel Chemistry Preprints 50 (2005).
  • T. Liu and G. Veser, "Temperature Dynamics during Catalytic Partial Oxidation of Methane in a Reverse-Flow Reactor", ACS Fuel Chemistry Preprints 50 (2005).
  • T. Liu, V. Gepert, and G. Veser, "Process Intensification through Heat Integration for High-Temperature Millisecond Contact-Time Catalysis", Proc. World Congress Chemical Engineering (WCCE-7), (2005).
  • S. Chattopadhyay and G. Veser, "Catalytic Microchannel Reactors as Intrinsically Safe Reactors", Proc. World Congress Chemical Engineering (WCCE-7), (2005).
  • M. Kirchhoff, T. Sanders, U. Specht, and G. Veser, "High-Temperature Stable Nanocomposite Catalysts", Proc. World Congress Chemical Engineering (WCCE-7), (2005).
  • 2004-2000
  • D. Neumann, V. Gepert, and G. Veser, "Some Considerations on the Design and Operation of High-Temperature Reverse-Flow Reactors", Ind. Eng. Chem. Res., 43 (2004) 4657-4667.
  • D. Neumann, M. Kirchhoff, and G. Veser, "Towards an Efficient Process for Small-Scale, Decentralized Conversion of Methane to Synthesis Gas: Combined Reactor Engineering and Catalyst Synthesis", Catal. Today, 68 (2004) 565-574.
  • A. Mitri, T. Liu, D. Neumann, and G. Veser, "Compensating and Predicting Catalyst Deactivation at High-Temperature Conditions through Reverse-Flow Reactor Operation", Chem. Eng. Sci., 59 (2004) 5527-5534.
  • D. Neumann, M. Kirchhoff, and G. Veser, "Towards an efficient process for small-scale, decentralized conversion of methane to synthesis gas or hydrogen", ACS Fuel Chemistry Preprints 49 (2004).
  • M. Kirchhoff, U. Specht, and G. Veser, "Synthesis and Characterization of High-Temperature Stable Nanocomposite Catalysts", Proc. NSTI Nanotechnology 2004, vol. 3, pp. 268-271.
  • J. Schicks, D. Neumann, U. Specht, and G. Veser, "Novel high-temperature catalysts for high-temperature partial oxidation reactions", Catal. Today 81 (2003) 287-296.
  • M. Kirchhoff, U. Specht, and G. Veser: "Novel Sol-Gel Derived Catalyst Systems for High-Temperature Partial Oxidation of Methane", in: "Innovation in the Manufacture and Use of Hydrogen" (G. Emig et al., Eds), DGMK Publishing, Hamburg, 2003, pp. 33-40
  • D. Neumann and G. Veser, "Syngas Production by Direct Oxidation of Methane in a Reverse-Flow Reactor", ACS Fuel Chemistry Preprints 48 (2003) 224-226.
  • M. Kirchhoff, U. Specht, and G. Veser, "Microemulsion-Templated Synthesis of Highly Active, High-Temperature Stable Partial Oxidation Catalysts", in: "Solid-State Ionics 2002" (Ph. Knauth et al., eds) MRS Proceedings 756 (2002) 891-896.
  • G. Veser, "Experimental and theoretical investigation of H2-oxidation in a high-temperature catalytic microreactor", Chem. Eng. Sci. 56 (2001) 1265-1273.
  • G. Veser, "Reaction Engineering for High-Temperature Partial Oxidation Reactions", Proc. 6th World Congr. Chem. Eng., Melbourne, Australia, (2001).
  • G. Veser, "Reactor Concepts for High-Temperature Catalytic Oxidations", Chem.-Ing.-Tech. 73 (2001) 774.
  • S. Chattopadhyay and G. Veser, "Detailed Simulations of Catalytic and Non-Catalytic Ignition during H2-Oxidation in a Microchannel Reactor", Proc. ChemConn2001, Chennai, India, (2001).
  • G. Veser and J. Frauhammer, "Modeling steady state and ignition of catalytic methane oxidation in a monolith reactor", Chem. Eng. Sci. 55 (2000) 2271-2286.
  • G. Veser, G. Friedrich, M. Freygang, and R. Zengerle, "A modular micro-reactor design for high-temperature catalytic oxidation reactions", in: "Microreaction Technology: Industrial Prospects", W. Ehrfeld (Ed.), Springer-Verlag, Berlin/Heidelberg, 2000, pp. 674-686.
  • G. Veser, "Multifunctional reactor concepts for syngas formation by direct oxidation of methane", Chem. Technol. (March/April 2000) 37-41.
  • U. Friedle, J. Frauhammer, and G. Veser, "Syngas formation by direct oxidation of methane: reaction mechanism and new reactor concepts", Catal. Today 61 (2000) 55-64.
  • M. Davis, M. Pawson, G. Veser and L.D. Schmidt, "Methane oxidation over noble metal gauzes: an LIF study", Comb. Flame 123 (2000) 159-174.
  • J. Schicks, U. Friedle and G. Veser, "Synthesis gas by direct oxidation of methane in a catalytic heat-exchange reactor", in: "Synthesis Gas Chemistry" (D. Hoenicke et al., Eds), DGMK Publishing, Hamburg, 2000, pp. 53-60.
  • J. Frauhammer and G. Veser, "A moving-grid algorithm for simulations of steep reaction fronts", Proc. IMACS-16 (2000).
  • 20th century...
  • G. Veser, M. Ziauddin and L.D. Schmidt, "Ignition during alkane oxidation over noble metal catalysts", Catal. Today 47 (1999) 219-228.
  • U. Friedle and G. Veser, "A counter-current heat-exchange reactor for high temperature partial oxidation reactions, part I: Experiments", Chem. Eng. Sci. 54 (1999) 1325-1332.
  • G. Veser, G. Friedrich, M. Freygang, and R. Zengerle, "A simple and flexible microreactor for studies of heterogeneously catalyzed gas phase reactions", Stud. Surf. Sci. Catal., 122(1999) 237-246.
  • G. Veser, A.G. Wright and R.A. Caretta, "Oxidation-reduction kinetics of palladium catalysts", Catal. Lett. 58 (1999) 1325-1332.
  • J. Frauhammer and G. Veser, "Gezielte Reaktionssteuerung durch Einstellen der Katalysatorbedeckungen in einem katalytischen Membranreaktor", Chem.-Ing.-Tech., 71 (1999) 976-977.
  • G. Veser, M. Freygang, and R. Zengerle, "A micro reaction tool for heterogeneous catalytic gas phase reactions", Proc. Int'l Micro Electro-Mechanical Systems Conference (MEMS`99), IEEE Piscataway, 1999, pp. 394-399.
  • J. Frauhammer and G. Veser, "Elementarkinetische Modelierung der katalytischen Direktoxidation von Methan zu Synthesegas in einem Monolithreaktor", Chem.-Ing.-Tech. 70 (1998) 1020-1027.
  • G. Veser, G. Friedrich, M. Freygang, and R. Zengerle, "A simple and flexible microreactor for investigations of heterogeneous catalytic gas phase reactions", ASME-DSC 66 (1998), 199-206.
  • M. Ziauddin, G. Veser, and L.D. Schmidt, "Ignition-extinction of ethane-air mixtures over noble metals", Catal. Letters 46 (1997) 159-167.
  • G. Veser, J. Frauhammer, L.D. Schmidt, and G. Eigenberger, "Catalytic ignition in methane oxidation on platinum: experiments and modeling", Stud. Surf. Sci. Catal., 109 (1997) 273-284.
  • G. Kolios, G. Veser and G. Eigenberger, "Catalytic membrane reactors for selective oxidation reactions", Proc. 4th European Workshop on Membrane Reactors, Oslo, NO, 1997, pp. 209-214.
  • G. Veser and L.D. Schmidt, "Ignition and extinction in the catalytic oxidation of hydrocarbons over platinum", AIChE J. 45 (1996) 1077-1087.
  • M.D. Graham, I.G. Kevrekidis, J.L. Hudson, G. Veser, K. Krischer and R. Imbihl, "Dynamics of concentration patterns of the NO+CO reaction on Pt: Analysis with the Karhunen-Loeve Decomposition", Chaos, Solitons & Fractals 5 (1995) 1817-1831.
  • N. Krustova, G. Veser, A.S. Mikhailov and R.Imbihl, "Delay induced chaos in catalytic surface reactions", Phys. Rev. Lett. 75 (1995) 3564-3567.
  • F. Mertens, A.S. Mikhailov, G. Veser, and R. Imbihl, "Synchronization and breakdown of global coupling in oscillatory surface reactions", in: "Chaos and Complexity", J. Tran Than Van et al. (eds), Editions Frontieres, Gif-sur-Yvette, 1995, pp. 285-294.
  • R. Imbihl and G. Veser, "Synchronization in oscillatory surface reactions on single crystal surfaces", J. Vac. Sci. Technol. A12 (1994) 2170-2175.
  • G. Veser, P. Thiel and R. Imbihl, "Homogeneous and heterogeneous front nucleation in a bistable surface reaction", J. Phys. Chem. 98 (1994) 2148-2151.
  • G. Veser and R. Imbihl, "Synchronization and spatiotemporal selforganisation in the NO+CO reaction on Pt(100). Part I: Unsychronized oscillations on the 1x1-substrate", J. Chem. Phys. 100 (1994) 8483-8491.
  • G. Veser and R. Imbihl, "Synchronization and spatiotemporal selforganisation in the NO+CO reaction on Pt(100). Part II: Synchronized oscillations on the hex-substrate", J. Chem. Phys. 100 (1994) 8492-8500.
  • G. Veser, F. Mertens, A. Mikhailov and R. Imbihl, "Global coupling in the presence of defects: Synchronization in an oscillatory surface reaction", Phys. Rev. Lett. 71 (1993) 935-938.
  • G. Veser and R. Imbihl, "Spatial pattern formation in the oscillatory NO+CO reaction on a Pt(100) surface and its vicinal orientations", J. Chem. Phys. 96 (1992) 7155-7163.
  • G. Veser, F. Esch, and R. Imbihl, "Regular and irregular spatial patterns in the catalytic reduction of NO with NH3 on Pt(100)", Catal. Lett. 13 (1992) 371-382.
  • G. Veser, R. Imbihl, "Spatial pattern formation in the catalytic NO+CO reaction on a cylindrical Pt single crystal", Surf. Sci. 269/270 (1992) 465.
  • M. Sander, G. Veser, and R. Imbihl, "Spirals and propagating reaction fronts during catalytic CO oxidation on a cylindrical Pt single crystal", J. Vac. Sci. Technol. A10 (1992) 2495-2500.

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