Operando XAS Study of Pt-Doped CeO2 for the Nonoxidative Conversion of Methane

: The methane to ole fi ns, aromatics, and hydrogen (MTOAH) process via Pt/CeO 2 catalysts poses an attractive route to improve yield and stability for the direct catalytic conversion of methane. In this study, two sets of samples, one composed of PtO x single sites on ceria and the other with additional Pt agglomerates, were prepared. Both sets of samples showed enhanced catalytic activity for the direct conversion of methane exceeding the performance of pure ceria. Pulsed reaction studies unraveled three reaction stages: reduction of the ceria support during activation, an induction phase with increasing product formation, and fi nally, stable running of the catalytic reactions. The reduction of ceria was con fi rmed by X-ray absorption spectroscopy (XAS) after conducting the MTOAH reaction. Operando X-ray absorption spectroscopy at challenging reaction temperatures of up to 975 ° C in combination with theoretical simulations further evidenced an increased Pt − Ce interaction upon reaction with CH 4 . Analysis of the extended X-ray absorption fi ne structure (EXAFS) spectra proved decoration and encapsulation of the Pt particles by the CeO 2 /Ce 2 O 3 support or a partial Ce − Pt alloy formation due to the strong metal − support interaction that developed under reaction conditions. Moreover, methyl radicals were detected as reaction intermediates indicating a reaction pathway through the gas-phase coupling of methyl radicals. The results indicate that apart from single-atom Pt sites reported in the literature, the observed Pt − Ce interface may have eased the activation of CH 4 by forming methyl radicals and suppressed coke formation, signi fi cantly improving the catalytic performance of the ceria-based catalysts in general. XAS product XANES/thermogravimetric studies, LCF, and EXAFS fi tting results exemplary FEFF input fi le

[1]  E. Wachsman,et al.  Direct Nonoxidative Methane Conversion in an Autothermal Hydrogen‐Permeable Membrane Reactor , 2021, Advanced Energy Materials.

[2]  D. Palagin,et al.  Temperature and Reaction Environment Influence the Nature of Platinum Species Supported on Ceria , 2021, ACS Catalysis.

[3]  Lin Zhou,et al.  Direct methane activation by atomically thin platinum nanolayers on two-dimensional metal carbides , 2021, Nature Catalysis.

[4]  P. Hemberger,et al.  Direct Evidence on the Mechanism of Methane Conversion under Non‐oxidative Conditions over Iron‐modified Silica: The Role of Propargyl Radicals Unveiled , 2021, Angewandte Chemie.

[5]  J. Grunwaldt,et al.  Versatile and high temperature spectroscopic cell for operando fluorescence and transmission x-ray absorption spectroscopic studies of heterogeneous catalysts. , 2021, The Review of scientific instruments.

[6]  L. Lefferts,et al.  Influence of Axial Temperature Profiles on Fe/SiO2 Catalyzed Non‐oxidative Coupling of Methane , 2020, ChemCatChem.

[7]  F. Studt,et al.  Tracking the formation, fate and consequence for catalytic activity of Pt single sites on CeO2 , 2020, Nature Catalysis.

[8]  A. Pohar,et al.  Micro-kinetics of non-oxidative methane coupling to ethylene over Pt/CeO2 catalyst , 2020 .

[9]  A. Datye,et al.  Strong metal-support interaction (SMSI) of Pt/CeO2 and its effect on propane dehydrogenation , 2020, Catalysis Today.

[10]  Jinghong Wen,et al.  Methane Nonoxidative Direct Conversion to C2 Hydrogenations over CeO2-Supported Pt Catalysts: A Density Functional Theory Study , 2020 .

[11]  B. Sumpter,et al.  Radical Chemistry and Reaction Mechanisms of Propane Oxidative Dehydrogenation over Hexagonal Boron Nitride Catalysts. , 2020, Angewandte Chemie.

[12]  A. Horton,et al.  Non-oxidative methane coupling over silica versus silica-supported iron(II) single sites. , 2020, Chemistry.

[13]  Jihan Kim,et al.  Highly durable metal ensemble catalysts with full dispersion for automotive applications beyond single-atom catalysts , 2020, Nature Catalysis.

[14]  Jiuzhong Yang,et al.  Formation and Fate of Formaldehyde in the Methanol-To-Hydrocarbons Reaction: An In Situ Synchrotron Radiation Photoionization Mass Spectrometry Study. , 2020, Angewandte Chemie.

[15]  H. J. Kim,et al.  Front Cover: Design of Ceria Catalysts for Low‐Temperature CO Oxidation (ChemCatChem 1/2020) , 2020 .

[16]  Hao Shen,et al.  Enhanced Methane Conversion to Olefins and Aromatics by H-Donor Molecules under Nonoxidative Condition , 2019, ACS Catalysis.

[17]  D. Lu,et al.  Local Structure and Electronic State of Atomically Dispersed Pt Supported on Nanosized CeO2 , 2019, ACS Catalysis.

[18]  Seung Ju Han,et al.  Nonoxidative Direct Conversion of Methane on Silica-Based Iron Catalysts: Effect of Catalytic Surface , 2019, ACS Catalysis.

[19]  Lina Cao,et al.  Insight of the stability and activity of platinum single atoms on ceria , 2019, Nano Research.

[20]  Jiuzhong Yang,et al.  Gas-Phase Reaction Network of Li/MgO-Catalyzed Oxidative Coupling of Methane and Oxidative Dehydrogenation of Ethane , 2019, ACS Catalysis.

[21]  R. Moos,et al.  Oxidation State and Dielectric Properties of Ceria-Based Catalysts by Complementary Microwave Cavity Perturbation and X-Ray Absorption Spectroscopy Measurements , 2019, Topics in Catalysis.

[22]  M. Herrmann,et al.  A beamline for bulk sample x-ray absorption spectroscopy at the high brilliance storage ring PETRA III , 2019 .

[23]  V. Svetlichnyi,et al.  Structural Insight into Strong Pt–CeO2 Interaction: From Single Pt Atoms to PtOx Clusters , 2018, The Journal of Physical Chemistry C.

[24]  O. Deutschmann,et al.  Regeneration of Sulfur Poisoned Pd–Pt/CeO2–ZrO2–Y2O3–La2O3 and Pd–Pt/Al2O3 Methane Oxidation Catalysts , 2018, Topics in Catalysis.

[25]  Xin Huang,et al.  Coke distribution determines the lifespan of a hollow Mo/HZSM-5 capsule catalyst in CH4 dehydroaromatization , 2018 .

[26]  E. Hensen,et al.  Structure and Evolution of Confined Carbon Species during Methane Dehydroaromatization over Mo/ZSM-5 , 2018, ACS catalysis.

[27]  F. Kapteijn,et al.  On the dynamic nature of Mo sites for methane dehydroaromatization† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c8sc01263f , 2018, Chemical science.

[28]  J. Grunwaldt,et al.  Tuning the Pt/CeO2 Interface by in Situ Variation of the Pt Particle Size , 2018 .

[29]  D. Su,et al.  Nanoceria-Supported Single-Atom Platinum Catalysts for Direct Methane Conversion , 2018 .

[30]  M. Fedin,et al.  Confined Carbon Mediating Dehydroaromatization of Methane over Mo/ZSM‐5 , 2017, Angewandte Chemie.

[31]  Jiuzhong Yang,et al.  Pyrolysis of n-Butylbenzene at Various Pressures: Influence of Long Side-Chain Structure on Alkylbenzene Pyrolysis , 2017 .

[32]  Xinhe Bao,et al.  Direct Conversion of Methane to Value-Added Chemicals over Heterogeneous Catalysts: Challenges and Prospects. , 2017, Chemical reviews.

[33]  Kanak Roy,et al.  Introducing Time Resolution to Detect Ce3+ Catalytically Active Sites at the Pt/CeO2 Interface through Ambient Pressure X-ray Photoelectron Spectroscopy. , 2017, The journal of physical chemistry letters.

[34]  J. Bokhoven,et al.  Evolution of the Atomic Structure of Ceria-Supported Platinum Nanocatalysts: Formation of Single Layer Platinum Oxide and Pt–O–Ce and Pt–Ce Linkages , 2016 .

[35]  Michelle H. Wiebenga,et al.  Thermally stable single-atom platinum-on-ceria catalysts via atom trapping , 2016, Science.

[36]  J. Grunwaldt,et al.  Structure and activity of flame made ceria supported Rh and Pt water gas shift catalysts , 2015 .

[37]  Konstantin M. Neyman,et al.  Maximum noble-metal efficiency in catalytic materials: atomically dispersed surface platinum. , 2014, Angewandte Chemie.

[38]  J. Grunwaldt,et al.  Fe and Mn‐Based Catalysts Supported on γ‐Al2O3 for CO Oxidation under O2‐Rich Conditions , 2014 .

[39]  Hongjun Fan,et al.  Direct, Nonoxidative Conversion of Methane to Ethylene, Aromatics, and Hydrogen , 2014, Science.

[40]  W. Grunwaldt 9.5: High Output Catalyst Development in Heterogeneous Gas Phase Catalysis , 2014 .

[41]  Weixin Huang,et al.  Methyl Radicals in Oxidative Coupling of Methane Directly Confirmed by Synchrotron VUV Photoionization Mass Spectroscopy , 2013, Scientific Reports.

[42]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[43]  F. Qi,et al.  Recent developments in synchrotron vacuum ultraviolet photoionization coupled to mass spectrometry , 2011 .

[44]  T. Janssens,et al.  The Cu Promoter in an Iron−Chromium−Oxide Based Water−Gas Shift Catalyst under Industrial Conditions Studied by in-Situ XAFS , 2010 .

[45]  J. Rehr,et al.  Parameter-free calculations of X-ray spectra with FEFF9. , 2010, Physical chemistry chemical physics : PCCP.

[46]  M. Lorenz,et al.  Microscopic insights into methane activation and related processes on Pt/ceria model catalysts. , 2010, Chemphyschem : a European journal of chemical physics and physical chemistry.

[47]  J. Fierro,et al.  A Comparative Study of the Water Gas Shift Reaction Over Platinum Catalysts Supported on CeO2, TiO2 and Ce-Modified TiO2 , 2010 .

[48]  Michael J. Economides,et al.  The state of natural gas , 2009 .

[49]  M Newville,et al.  ATHENA, ARTEMIS, HEPHAESTUS: data analysis for X-ray absorption spectroscopy using IFEFFIT. , 2005, Journal of synchrotron radiation.

[50]  D. Su,et al.  Platinum nanocrystals supported by silica, alumina and ceria: metal-support interaction due to high-temperature reduction in hydrogen , 2003 .

[51]  K. P. Jong,et al.  Preparation of Highly Dispersed Pt Particles in Zeolite Y with a Narrow Particle Size Distribution : Characterization by Hydrogen Chemisorption, TEM, EXAFS Spectroscopy, and Particle Modeling , 2001 .

[52]  Y. Nakamori,et al.  Magnetic and electrical properties of R7Rh3 (R=Gd, Tb, Dy, Ho, Er and Y) , 2001 .

[53]  J. Rehr,et al.  Theoretical approaches to x-ray absorption fine structure , 2000 .

[54]  Linsheng Wang,et al.  Catalytic Dehydrocondensation of Methane with CO and CO2toward Benzene and Naphthalene on Mo/HZSM-5 and Fe/Co-Modified Mo/HZSM-5 , 1999 .

[55]  W. Cui,et al.  Study on the induction period of methane aromatization over Mo/HZSM-5: partial reduction of Mo species and formation of carbonaceous deposit , 1999 .

[56]  J. I. Espeso,et al.  Crystallographic study and magnetic structures of CeNixPt1-x and diluted related compounds , 1993 .

[57]  Jiasheng Huang,et al.  Dehydrogenation and aromatization of methane under non-oxidizing conditions , 1993 .

[58]  A. Palenzona The crystal structure and lattice constants of R3Pt4 compounds , 1977 .

[59]  N. Krikorian The reaction of selected lanthanide carbides with platinum and iridium , 1971 .

[60]  H. Hoekstra,et al.  The crystal structure of beta-platinum dioxide , 1969 .

[61]  N. Baenziger,et al.  X‐ray examination of some rare‐earth‐containing binary alloy systems , 1966 .

[62]  Konstantin M. Neyman,et al.  Study of active surface centers of Pt/CeO2 catalysts prepared using radio-frequency plasma sputtering technique , 2019, Surface Science.

[63]  G. Stucky,et al.  Supplementary Material for Identification of active sites in CO oxidation and water-gas shift over supported Pt catalysts , 2015 .

[64]  Andrew McIlroy,et al.  Studies of a fuel-rich propane flame with photoionization mass spectrometry , 2005 .

[65]  G. E. Keller,et al.  Synthesis of ethylene via oxidative coupling of methane: I. Determination of active catalysts , 1982 .

[66]  P. Mériaudeau,et al.  Further Investigation on Metal-Support Interaction: TiO2, CeO2, SiO2 Supported Platinum Catalysts , 1982 .

[67]  S. C. Fung,et al.  Strong metal-support interactions. Group 8 noble metals supported on titanium dioxide , 1978 .