Dynamic Evolution of Palladium Single Atoms on Anatase Titania Support Determines the Reverse Water-Gas Shift Activity.

Research interest in single-atom catalysts (SACs) has been continuously increasing. However, the lack of understanding of the dynamic behaviors of SACs during applications hinders catalyst development and mechanistic understanding. Herein, we report on the evolution of active sites over Pd/TiO2-anatase SAC (Pd1/TiO2) in the reverse water-gas shift (rWGS) reaction. Combining kinetics, in situ characterization, and theory, we show that at T ≥ 350 °C, the reduction of TiO2 by H2 alters the coordination environment of Pd, creating Pd sites with partially cleaved Pd-O interfacial bonds and a unique electronic structure that exhibit high intrinsic rWGS activity through the carboxyl pathway. The activation by H2 is accompanied by the partial sintering of single Pd atoms (Pd1) into disordered, flat, ∼1 nm diameter clusters (Pdn). The highly active Pd sites in the new coordination environment under H2 are eliminated by oxidation, which, when performed at a high temperature, also redisperses Pdn and facilitates the reduction of TiO2. In contrast, Pd1 sinters into crystalline, ∼5 nm particles (PdNP) during CO treatment, deactivating Pd1/TiO2. During the rWGS reaction, the two Pd evolution pathways coexist. The activation by H2 dominates, leading to the increasing rate with time-on-stream, and steady-state Pd active sites similar to the ones formed under H2. This work demonstrates how the coordination environment and nuclearity of metal sites on a SAC evolve during catalysis and pretreatments and how their activity is modulated by these behaviors. These insights on SAC dynamics and the structure-function relationship are valuable to mechanistic understanding and catalyst design.

[1]  L. Kovarik,et al.  Disordered, Sub-Nanometer Ru Structures on CeO2 are Highly Efficient and Selective Catalysts in Polymer Upcycling by Hydrogenolysis , 2022, ACS Catalysis.

[2]  L. Kovarik,et al.  Temperature-Dependent Communication between Pt/Al2O3 Catalysts and Anatase TiO2 Dilutant: the Effects of Metal Migration and Carbon Transfer on the Reverse Water–Gas Shift Reaction , 2021, ACS Catalysis.

[3]  R. Behm,et al.  Controlling the O-Vacancy Formation and Performance of Au/ZnO Catalysts in CO2 Reduction to Methanol by the ZnO Particle Size , 2021, ACS Catalysis.

[4]  R. Behm,et al.  Steering the selectivity in CO2 reduction on highly active Ru/TiO2 catalysts: Support particle size effects , 2021 .

[5]  R. Unocic,et al.  Unlocking the Catalytic Potential of TiO2-Supported Pt Single Atoms for the Reverse Water–Gas Shift Reaction by Altering Their Chemical Environment , 2021, JACS Au.

[6]  E. Hensen,et al.  Interface dynamics of Pd–CeO2 single-atom catalysts during CO oxidation , 2021, Nature Catalysis.

[7]  A. Frenkel,et al.  Deciphering the Local Environment of Single-Atom Catalysts with X-ray Absorption Spectroscopy. , 2021, Accounts of chemical research.

[8]  L. Grabow,et al.  Kinetics of H2 Adsorption at the Metal-Support Interface of Au/TiO2 Catalysts probed by Broad Background IR Absorbance. , 2021, Angewandte Chemie.

[9]  N. Nelson,et al.  In Situ Dispersion of Pd on TiO2 During Reverse Water-Gas Shift Reaction: Formation of Atomically Dispersed Pd. , 2020, Angewandte Chemie.

[10]  Yadong Li,et al.  Well-Defined Materials for Heterogeneous Catalysis: From Nanoparticles to Isolated Single-Atom Sites. , 2019, Chemical reviews.

[11]  N. Nelson,et al.  Heterolytic Hydrogen Activation: Understanding Support Effects in Water–Gas Shift, Hydrodeoxygenation, and CO Oxidation Catalysis , 2019, ACS Catalysis.

[12]  Xiaoqing Pan,et al.  Rh single atoms on TiO2 dynamically respond to reaction conditions by adapting their site , 2019, Nature Communications.

[13]  R. Rousseau,et al.  Carboxyl intermediate formation via an in situ-generated metastable active site during water-gas shift catalysis , 2019, Nature Catalysis.

[14]  A. Beale,et al.  Tuning of catalytic sites in Pt/TiO2 catalysts for the chemoselective hydrogenation of 3-nitrostyrene , 2019, Nature Catalysis.

[15]  S. Oh,et al.  Surpassing the single-atom catalytic activity limit through paired Pt-O-Pt ensemble built from isolated Pt1 atoms , 2019, Nature Communications.

[16]  N. López,et al.  Dynamic charge and oxidation state of Pt/CeO2 single-atom catalysts , 2019, Nature Materials.

[17]  R. Schlögl,et al.  Negative Charging of Au Nanoparticles during Methanol Synthesis from CO2 /H2 on a Au/ZnO Catalyst: Insights from Operando IR and Near-Ambient-Pressure XPS and XAS Measurements. , 2019, Angewandte Chemie.

[18]  B. D. Kay,et al.  Understanding Heterolytic H2 Cleavage and Water-Assisted Hydrogen Spillover on Fe3O4(001)-Supported Single Palladium Atoms , 2019, ACS Catalysis.

[19]  G. E. Sterbinsky,et al.  Alkene Hydrosilylation on Oxide‐Supported Pt‐Ligand Single‐Site Catalysts , 2019, ChemCatChem.

[20]  R. Schlögl,et al.  The Influence of CO on the Activation, O-Vacancy Formation and Performance of Au/ZnO Catalysts in CO2 Hydrogenation to Methanol. , 2019, The journal of physical chemistry letters.

[21]  Gianfranco Pacchioni,et al.  Structural evolution of atomically dispersed Pt catalysts dictates reactivity , 2019, Nature Materials.

[22]  Junming Zhang,et al.  In Situ/Operando Techniques for Characterization of Single-Atom Catalysts , 2019, ACS Catalysis.

[23]  Jie Zeng,et al.  Static Regulation and Dynamic Evolution of Single‐Atom Catalysts in Thermal Catalytic Reactions , 2018, Advanced science.

[24]  Dequan Xiao,et al.  Atomically Dispersed Pd on Nanodiamond/Graphene Hybrid for Selective Hydrogenation of Acetylene. , 2018, Journal of the American Chemical Society.

[25]  L. Grabow,et al.  H2 Oxidation over Supported Au Nanoparticle Catalysts: Evidence for Heterolytic H2 Activation at the Metal-Support Interface. , 2018, Journal of the American Chemical Society.

[26]  G. E. Sterbinsky,et al.  Synthesis of platinum single-site centers through metal-ligand self-assembly on powdered metal oxide supports , 2018, Journal of Catalysis.

[27]  U. Diebold,et al.  High-affinity adsorption leads to molecularly ordered interfaces on TiO2 in air and solution , 2018, Science.

[28]  P. Midgley,et al.  A heterogeneous single-atom palladium catalyst surpassing homogeneous systems for Suzuki coupling , 2018, Nature Nanotechnology.

[29]  M. Beller,et al.  Bridging homogeneous and heterogeneous catalysis by heterogeneous single-metal-site catalysts , 2018, Nature Catalysis.

[30]  D. Dixon,et al.  Beating Heterogeneity of Single-Site Catalysts: MgO-Supported Iridium Complexes , 2018 .

[31]  Ying Dai,et al.  Effects of single metal atom (Pt, Pd, Rh and Ru) adsorption on the photocatalytic properties of anatase TiO 2 , 2017 .

[32]  Xiaoqing Pan,et al.  Catalyst Architecture for Stable Single Atom Dispersion Enables Site-Specific Spectroscopic and Reactivity Measurements of CO Adsorbed to Pt Atoms, Oxidized Pt Clusters, and Metallic Pt Clusters on TiO2. , 2017, Journal of the American Chemical Society.

[33]  B. Gates,et al.  Tuning the Selectivity of Single-Site Supported Metal Catalysts with Ionic Liquids , 2017 .

[34]  Xiang Wang,et al.  Controlling selectivities in CO2 reduction through mechanistic understanding , 2017, Nature Communications.

[35]  R. Behm,et al.  Influence of TiO2 Bulk Defects on CO Adsorption and CO Oxidation on Au/TiO2: Electronic Metal–Support Interactions (EMSIs) in Supported Au Catalysts , 2017 .

[36]  Xiang Wang,et al.  Kinetic modeling and transient DRIFTS–MS studies of CO 2 methanation over Ru/Al 2 O 3 catalysts , 2016 .

[37]  B. Gates,et al.  Homogeneity of Surface Sites in Supported Single-Site Metal Catalysts: Assessment with Band Widths of Metal Carbonyl Infrared Spectra. , 2016, The journal of physical chemistry letters.

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

[39]  L. Gu,et al.  Photochemical route for synthesizing atomically dispersed palladium catalysts , 2016, Science.

[40]  U. Diebold,et al.  An Atomic-Scale View of CO and H2 Oxidation on a Pt/Fe3 O4 Model Catalyst. , 2015, Angewandte Chemie.

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

[42]  J. Kwak,et al.  Mechanism of CO2 Hydrogenation on Pd/Al2O3 Catalysts: Kinetics and Transient DRIFTS-MS Studies , 2015 .

[43]  D. Foix,et al.  Phase stability frustration on ultra-nanosized anatase TiO2 , 2015, Scientific Reports.

[44]  M. Flytzani-Stephanopoulos,et al.  A common single-site Pt(II)-O(OH)x- species stabilized by sodium on "active" and "inert" supports catalyzes the water-gas shift reaction. , 2015, Journal of the American Chemical Society.

[45]  Donghai Mei,et al.  Dynamic formation of single-atom catalytic active sites on ceria-supported gold nanoparticles , 2015, Nature Communications.

[46]  Vanessa N Yang,et al.  Isolated metal active site concentration and stability control catalytic CO2 reduction selectivity. , 2015, Journal of the American Chemical Society.

[47]  Zhiwei Huang,et al.  Electronic metal-support interactions in single-atom catalysts. , 2014, Angewandte Chemie.

[48]  Ping Liu,et al.  CO2 hydrogenation on Au/TiC, Cu/TiC, and Ni/TiC catalysts: Production of CO, methanol, and methane , 2013 .

[49]  L. Kovarik,et al.  CO2 Reduction on Supported Ru/Al2O3 Catalysts: Cluster Size Dependence of Product Selectivity , 2013 .

[50]  L. Kovarik,et al.  Heterogeneous Catalysis on Atomically Dispersed Supported Metals: CO2 Reduction on Multifunctional Pd Catalysts , 2013 .

[51]  Ulrike Diebold,et al.  Carbon monoxide-induced adatom sintering in a Pd-Fe3O4 model catalyst. , 2013, Nature materials.

[52]  R. Behm,et al.  TAP reactor studies of the oxidizing capability of CO2 on a Au/CeO2 catalyst – A first step toward identifying a redox mechanism in the Reverse Water–Gas Shift reaction , 2013 .

[53]  S. Bare,et al.  EXAFS Model of 2-Dimensional Platinum Clusters , 2013 .

[54]  N. Browning,et al.  Oxide- and zeolite-supported isostructural Ir(C2H4)2 complexes: molecular-level observations of electronic effects of supports as ligands. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[55]  G. Thornton,et al.  Acetic Acid Adsorption on Anatase TiO2(101) , 2012 .

[56]  E. A. Lewis,et al.  Isolated Metal Atom Geometries as a Strategy for Selective Heterogeneous Hydrogenations , 2012, Science.

[57]  L. Giordano,et al.  Tailoring the shape of metal ad-particles by doping the oxide support. , 2011, Angewandte Chemie.

[58]  P. Serna,et al.  Zeolite- and MgO-Supported Molecular Iridium Complexes: Support and Ligand Effects in Catalysis of Ethene Hydrogenation and H–D Exchange in the Conversion of H2 + D2 , 2011 .

[59]  G. Pacchioni,et al.  Hydrogen Adsorption and Diffusion on the Anatase TiO2(101) Surface: A First-Principles Investigation , 2011 .

[60]  L. Österlund,et al.  Adsorption and Photoinduced Decomposition of Acetone and Acetic Acid on Anatase, Brookite, and Rutile TiO2 Nanoparticles , 2010 .

[61]  G. Pacchioni,et al.  Reduced and n-Type Doped TiO2: Nature of Ti3+ Species , 2009 .

[62]  Donghai Mei,et al.  Coordinatively Unsaturated Al3+ Centers as Binding Sites for Active Catalyst Phases of Platinum on γ-Al2O3 , 2009, Science.

[63]  A. Selloni,et al.  Energetics and diffusion of intrinsic surface and subsurface defects on anatase TiO2(101). , 2009, The Journal of chemical physics.

[64]  J. Regalbuto,et al.  The synthesis of highly dispersed noble and base metals on silica via strong electrostatic adsorption: I. Amorphous silica , 2008 .

[65]  T. Risse,et al.  Gold supported on thin oxide films: from single atoms to nanoparticles. , 2008, Accounts of chemical research.

[66]  Q. Ge,et al.  Effect of Surface Oxygen Vacancy on Pt Cluster Adsorption and Growth on the Defective Anatase TiO2(101) Surface , 2007 .

[67]  J. Yates,et al.  Spectroscopic Detection of Hydrogen Atom Spillover from Au Nanoparticles Supported on TiO2: Use of Conduction Band Electrons , 2007 .

[68]  Darrin S. Muggli,et al.  Active sites and effects of H2O and temperature on the photocatalytic oxidation of 13C-acetic acid on TiO2 , 2005 .

[69]  H. Freund,et al.  CO adsorption on oxide supported gold: from small clusters to monolayer islands and three-dimensional nanoparticles , 2004 .

[70]  A. Jentys,et al.  Estimation of mean size and shape of small metal particles by EXAFS , 1999 .

[71]  J. Banfield,et al.  Thermodynamic analysis of phase stability of nanocrystalline titania , 1998 .

[72]  V. Ponec,et al.  On the intermediates of the acetic acid reactions on oxides : an IR study , 1996 .

[73]  G. Bond,et al.  Effect of Various Pretreatments on the Structure and Properties of Ruthenium Catalysts , 1996 .

[74]  K. Hadjiivanov,et al.  Surface chemistry of titania (anatase) and titania-supported catalysts , 1996 .

[75]  Jeffrey T. Miller,et al.  Influence of Hydrogen Pretreatment on the Structure of the Metal-Support Interface in Pt/Zeolite Catalysts , 1993 .

[76]  T. Bein,et al.  Stabilization of Metal Ensembles at Room Temperature: Palladium Clusters in Zeolites. , 1989 .

[77]  R. Prins,et al.  Structure of rhodium/titania in the normal and the SMSI state as determined by extended x-ray absorption fine structure and high-resolution transmission electron microscopy , 1988 .

[78]  B. Gates,et al.  Highly dispersed rhodium on alumina catalysts: influence of the atmosphere on the state and dispersion of rhodium , 1987 .

[79]  F. Solymosi,et al.  Catalytic hydrogenation of CO2 over supported palladium , 1986 .

[80]  D. Sayers,et al.  An Extended X-ray Absorption Fine Structure Study of Rhodium-Oxygen Bonds in a Highly Dispersed Rhodium/Aluminum Oxide Catalyst , 1985 .

[81]  D. Sayers,et al.  An EXAFS study of platinum-oxygen bonds in the metal-support interface of a highly dispersed Pt/Al2O3 catalyst , 1985 .

[82]  R. Prins,et al.  Structure of rhodium in an ultradispersed Rh/Al2O3 catalyst as studied by EXAFS and other techniques , 1985 .

[83]  M. Vannice,et al.  Determination of IR extinction coefficients for linear- and bridged-bonded carbon monoxide on supported palladium , 1981 .