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Computational Catalysis PDF

276 Pages·2013·9.42 MB·English
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Computational Catalysis 1 0 0 P F 5- 0 9 4 3 7 9 4 8 1 8 7 9 9/ 3 0 1 0. 1 oi: d g | or c. s s.r b u p p:// htt n o 3 1 0 2 er b m e c e D 2 . n 0 o d e h s bli u P View Online RSC Catalysis Series Series Editor: Professor James J Spivey, Louisiana State University, Baton Rouge, USA 1 0 0 P F Advisory Board: 5- 90 Krijn P de Jong, University of Utrecht, The Netherlands, James A Dumesic, 4 73 University of Wisconsin-Madison, USA, Chris Hardacre, Queen’s University 9 84 Belfast, Northern Ireland, Enrique Iglesia, University of California at Berkeley, 1 8 USA, Zinfer Ismagilov, Boreskov Institute of Catalysis, Novosibirsk, Russia, 7 9 9/ JohannesLercher,TUMu¨nchen,Germany,UmitOzkan,OhioStateUniversity, 3 10 USA, Chunshan Song, Penn State University, USA 0. 1 oi: d Titles in the Series: g | or 1: Carbons and Carbon Supported Catalysts in Hydroprocessing sc. 2: Chiral Sulfur Ligands: Asymmetric Catalysis s.r b 3: Recent Developments in Asymmetric Organocatalysis u p p:// 4: Catalysis in the Refining of Fischer–Tropsch Syncrude htt 5: Organocatalytic Enantioselective Conjugate Addition Reactions: n o APowerfulToolfortheStereocontrolledSynthesisofComplexMolecules 3 1 6: N-Heterocyclic Carbenes: From Laboratory Curiosities to Efficient 0 2 er Synthetic Tools b m 7: P-Stereogenic Ligands in Enantioselective Catalysis e ec 8: Chemistry of the Morita–Baylis–Hillman Reaction D 2 9: Proton-Coupled Electron Transfer: A Carrefour of Chemical Reactivity . on 0 Traditions d e 10: Asymmetric Domino Reactions h s bli 11: C–H and C–X Bond Functionalization: Transition Metal Mediation u P 12: Metal Organic Frameworks as Heterogeneous Catalysts 13: Environmental Catalysis Over Gold-Based Materials 14: Computational Catalysis How to obtain future titles on publication: A standing order plan is available for this series. A standing order will bring delivery of each new volume immediately on publication. For further information please contact: BookSalesDepartment,RoyalSocietyofChemistry,ThomasGrahamHouse, Science Park, Milton Road, Cambridge, CB4 0WF, UK Telephone: +44(0)1223 420066,Fax:+44(0)1223420247 Email:[email protected] Visit our website atwww.rsc.org/books View Online Computational Catalysis 1 0 0 P F 5- Edited by 0 9 4 3 7 9 Aravind Asthagiri 4 8 81 Ohio State University, USA 7 9/9 Email: [email protected] 3 0 1 10. and oi: d g | or Michael J. Janik c. s.rs Pennsylvania State University, USA ub Email: [email protected] p p:// htt n o 3 1 0 2 er b m e c e D 2 . n 0 o d e h s bli u P View Online 1 0 0 P F 5- 0 9 4 3 7 9 4 8 1 8 7 9 9/ 3 0 1 0. 1 oi: d g | or c. s s.r b u p p:// htt n o RSCCatalysisSeriesNo.14 3 1 0 2 er ISBN:978-1-84973-451-6 mb ISSN:1757-6725 e c e D AcataloguerecordforthisbookisavailablefromtheBritishLibrary 2 . on 0 rTheRoyalSocietyofChemistry2014 d e h blis Allrightsreserved u P Apartfromfairdealingforthepurposesofresearchfornon-commercialpurposesorfor privatestudy,criticismorreview,aspermittedundertheCopyright,DesignsandPatents Act1988andtheCopyrightandRelatedRightsRegulations2003,thispublicationmaynot bereproduced,storedortransmitted,inanyformorbyanymeans,withouttheprior permissioninwritingofTheRoyalSocietyofChemistryorthecopyrightowner,orinthe caseofreproductioninaccordancewiththetermsoflicencesissuedbytheCopyright LicensingAgencyintheUK,orinaccordancewiththetermsofthelicencesissuedbythe appropriateReproductionRightsOrganizationoutsidetheUK.Enquiriesconcerning reproductionoutsidethetermsstatedhereshouldbesenttoTheRoyalSocietyof Chemistryattheaddressprintedonthispage. TheRSCisnotresponsibleforindividualopinionsexpressedinthiswork. PublishedbyTheRoyalSocietyofChemistry, ThomasGrahamHouse,SciencePark,MiltonRoad, CambridgeCB40WF,UK RegisteredCharityNumber207890 Forfurtherinformationseeourwebsiteatwww.rsc.org 5 0 0 P F 5- 90 Preface 4 3 7 9 4 8 1 8 7 9 9/ 3 0 1 0. 1 oi: The RSC Catalysis Book Series has been publishing books focused on many d g | aspectsofcatalysissincethe1970’s,buttodatetherehasnotbeenabookinthe or series that has solely focused on computational modeling of heterogeneous c. s.rs catalysis. The importance of computational catalysis has grown over the past ub twodecadesandthereareanincreasingnumberofyoungresearchersentering p p:// this area. The aim of this book is to provide a pedantic presentation of select htt methods in computational catalysis. Our hope is that this book will prove n 3 o useful to the graduate student or other researchers already familiar with 1 0 computer simulations, but interested in applying specific methods to their 2 er catalysis research. b m e In the first chapter, Lars Grabow (University of Houston) discusses the c De screeningofcatalyststhroughtheuseoffirst-principlesmethods.Usingdensity . n 02 functional theory (DFT), key descriptors and scaling relationships can be o identified and incorporated with an appropriate microkinetic model. Such an d he approach allows for the rapid screening of materials based on DFT s bli calculations. u P One of the key challenges in modeling catalysts is the need to predict the appropriate surface structure at reaction conditions. Jason Bray and Bill Schneider (Notre Dame) present a detailed example of a first-principles based thermodynamic model for oxygen adsorption on Pt surfaces. They derive a cluster expansion model, fit to DFT data, which allows for exploring the complexheterogeneousoxygenphaseasafunctionoftemperatureandoxygen partialpressureusingMonteCarlosimulations.Thesetypesofsimulationsalso allow for exploring surface reaction behavior under reaction conditions. Inthe third chapter,Kuan-YuYeh andMikeJanik (Penn State University) present a detailed review of DFT-based modeling of electrocatalysts. The electrochemicalinterfaceisoneofthemorechallengingenvironmentstomodel, and several different models that vary in accuracy and computational expense RSCCatalysisSeriesNo.14 ComputationalCatalysis EditedbyAravindAsthagiriandMichaelJ.Janik rTheRoyalSocietyofChemistry2014 PublishedbytheRoyalSocietyofChemistry,www.rsc.org v View Online vi Preface are presented. With these methods potential dependent reaction energies and barrierscanbecalculatedforelementarysteps.Specificexamplesarepresented to illustrate how to apply these various models. Another important area of computational catalysis is modeling the metal/ 05 oxide interface, which is discussed by Tom Senftle, Adri van Duin, and Mike 0 FP Janik(PennState).Theyreviewseveralapplications,suchasthewater-gasshift 5- 0 reaction and hydrocarbon activation, and the stability of oxide phases, that 9 4 3 applies both DFT-based calculations and charge transfer potentials. 7 9 4 Thomas Manz (New Mexico State University) and David Sholl (Georgia 8 1 8 Tech) present the details and application of their charge partitioning method 7 9/9 called the density derived electrostatic and chemical (DDEC) method. This 3 0 method can be used to obtain chemically relevant atomic charges and spin 1 10. momentsforbothperiodicandnon-periodicsystems.Suchoutputcanassistin doi: understanding the relationship between electronic structure and material g | properties,andcanalsobeusedasinputintothefittingofclassicalpotentials. or c. The last two chapters present details of two classical potentials that in- s bs.r corporatechargetransfer.AdrivanDuinandco-workerspresentthedetailsof u http://p twhoerkReerasxfFrFompottheentUianliavnedrsidtyiscoufssFsloevriedraalparpepselinctattihoensc.hSaursgaenoSpitninmoitztedanmdacnoy- n body(COMB)potentialsanditsapplicationtomoleculesandmetalsonoxide o 13 surfaces. 0 er 2 We appreciate the efforts made by the authors to present a wide range of mb important methods in computational catalysis at a level that can benefit a e c researcher learning these methods for their research. e D 2 . n 0 Aravind Asthagiri o d Michael J Janik e h s bli u P 7 0 0 P F 5- 90 Contents 4 3 7 9 4 8 1 8 7 9 9/ 3 10 Chapter 1 Computational Catalyst Screening 1 0. 1 Lars C. Grabow oi: d org | 1.1 Introduction 1 sc. 1.1.1 A Walk through a Computational Catalyst bs.r Design Process: Methanation 3 u p p:// 1.2 Starting from the Electronic Structure 4 htt 1.2.1 Density Functional Theory 4 on 1.2.2 The d-Band Model 6 3 1 1.3 Identifying the Right Descriptor Set 8 0 2 er 1.3.1 Scaling Relations for Surface b m Intermediates 9 e ec 1.3.2 Scaling Relations for Transition States: D 2 The Brønsted–Evans–Polanyi . n 0 Relationship 13 o ed 1.4 The Sabatier Principle and the Volcano Curve 17 h s bli 1.4.1 Sabatier Analysis 18 u P 1.5 Sabatier Analysis in Practice 20 1.5.1 First Example: Ammonia Synthesis 20 1.5.2 Second Example: CO Oxidation 25 1.6 Notes on Microkinetic Modeling 27 1.6.1 Numerical Solution Strategies 29 1.6.2 Entropy and Enthalpy Corrections 31 1.6.3 Microkinetic Model Analysis 32 1.7 CO Oxidation Catalyst Screening 35 1.7.1 Numerical Microkinetic Model 35 1.7.2 Degree of Rate and Catalyst Control 41 1.7.3 Two-dimensional CO Oxidation Volcano 44 1.7.4 Effect of Lateral Interactions 45 RSCCatalysisSeriesNo.14 ComputationalCatalysis EditedbyAravindAsthagiriandMichaelJ.Janik rTheRoyalSocietyofChemistry2014 PublishedbytheRoyalSocietyofChemistry,www.rsc.org vii View Online viii Contents 1.8 Conclusions 47 Appendix 48 References 55 7 0 0 Chapter 2 First-principles Thermodynamic Models in Heterogeneous P F 5- Catalysis 59 0 49 J. M. Bray and W. F. Schneider 3 7 9 4 18 2.1 Introduction 59 8 7 2.1.1 Background 59 9 39/ 2.1.2 Background on Oxygen Adsorption on 0 0.1 Platinum 62 1 oi: 2.2 Setting up the System 63 d g | 2.2.1 Developing a Slab Model 63 or 2.2.2 Identifying and Characterizing Adsorption c. s.rs Sites 65 b u 2.2.3 Increasing Coverage 69 p p:// 2.3 DevelopingaSelf-consistentClusterExpansionModel 72 htt 2.3.1 Cluster Expansion Fundamentals 72 n 3 o 2.3.2 Self-consistent Fitting Approach 74 1 0 2.4 Applying the Model to Obtain Physical Insight 80 2 er 2.4.1 Analysis of the DFT Fitting Database 80 b m e 2.4.2 Analysis of Ordered Ground States 83 c De 2.4.3 Monte Carlo Simulations 93 . n 02 2.4.4 Kinetic Properties from CE/GCMC Methods 109 o 2.5 Conclusions 112 d he Acknowledgments 112 s bli References 113 u P Chapter 3 Density Functional Theory Methods for Electrocatalysis 116 Kuan-Yu Yeh and Michael J. Janik 3.1 Introduction 116 3.1.1 A Motivating Example: H Oxidation/H 2 2 Evolution 117 3.1.2 Electrode Potential Effects on Reaction Energies and Activation Barriers 121 3.1.3 Electrochemical Double-layer Theory 122 3.1.4 Overview of DFT Models for Electrocatalysis 124 3.2 Examples Applying DFT Methods to Electrocatalysis 128 3.2.1 Simulating the Vacuum–Metal Interface 129 3.2.2 Simulating an Aqueous–Metal Interface 137 3.2.3 Linear Sweep Voltammetry Simulations 146 View Online Contents ix 3.2.4 Calculation of Surface Reaction Free Energies 147 3.2.5 Potential Dependent Activation Barriers 151 3.3 Conclusions 153 07 References 153 0 P F 5- 0 9 Chapter 4 Application of Computational Methods to Supported 4 3 7 Metal–Oxide Catalysis 157 9 4 8 ThomasP.Senftle,AdriC.T.vanDuinandMichaelJ.Janik 1 8 7 9 39/ 4.1 Introduction 157 0 0.1 4.2 Computational Approaches to Supported 1 oi: Metal–Oxide Catalysis 158 d g | 4.3 Selected Applications 159 or 4.3.1 Application of DFT to WGS 161 c. s.rs 4.3.2 Ab Initio Thermodynamics 167 b u 4.3.3 Classical Atomistic Modeling 174 p p:// 4.3.4 Combined Application: Hydrocarbon htt Activation over Pd/CeO 178 n 2 3 o 4.4 Conclusions 185 1 0 References 186 2 er b m ce Chapter 5 Computing Accurate Net Atomic Charges, Atomic Spin e D 2 Moments, and Effective Bond Orders in Complex . n 0 Materials 192 o d Thomas A. Manz and David S. Sholl e h s bli u 5.1 Introduction 192 P 5.2 Net Atomic Charges and Atomic Spin Moments 194 5.2.1 The Charge Partitioning Functional 194 5.2.2 The Spin Partitioning Functional 196 5.2.3 Example using VASP Software 198 5.2.4 Examples using GAUSSIAN Software 201 5.2.5 VASP Non-collinear Magnetism Example 205 5.3 Modeling the Electrostatic Potential Surrounding a Material 209 5.3.1 Atom-centered Distributed Multipole Expansion 209 5.3.2 Applications to Force-fields used in Atomistic Simulations 211 5.4 Effective Bond Orders 212 5.5 Conclusions 219 Acknowledgments 219 References 220 View Online x Contents Chapter6 AReaxffReactiveForce-fieldforProtonTransferReactions in Bulk Water and its Applications to Heterogeneous Catalysis 223 Adri C.T. van Duin, Chenyu Zou, Kaushik Joshi, 7 0 Vyascheslav Bryantsev and William A. Goddard 0 P F 5- 0 6.1 Introduction 223 9 4 3 6.2 Methods 226 7 9 4 6.2.1 Quantumchemical Methods 226 8 1 8 6.2.2 Force-field Optimization 226 7 9 9/ 6.3 Results and Discussion 226 3 10 6.3.1 Force-field Development 226 0. 1 6.3.2 Molecular Dynamics Simulations 233 oi: d 6.3.3 Heterogeneous Catalysis 238 org | 6.4 Conclusions 240 sc. References 240 s.r b u p://p Chapter 7 Charge Transfer Potentials 244 htt Yu-Ting Cheng, Tao Liang, Simon R. Phillpot and on Susan B. Sinnott 3 1 0 2 er 7.1 Introduction 244 b m 7.2 Variable Charge Reactive Potentials: COMB e c e Potentials 247 D 2 7.2.1 A General Form of the COMB Potentials 247 . on 0 7.2.2 Electrostatic Energies 247 d he 7.2.3 Short-range Interactions 249 s bli 7.2.4 van der Waals Interactions 251 u P 7.2.5 Correction Terms 251 7.2.6 Parameterization of the COMB Potential 251 7.3 Applications 255 7.3.1 Ethyl Radical Deposition on the Cu(111) Surface 255 7.3.2 Cu/ZnO Heterogeneous System 256 7.4 Conclusions 257 Acknowledgments 258 References 258 Subject Index 261

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The field of computational catalysis has existed in one form or another for at least 30 years. Its ultimate goal - the design of a novel catalyst entirely from the computer. While this goal has not been reached yet, the 21st Century has already seen key advances in capturing the myriad complex pheno
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