Scanning Tunneling Microscopy in Surface Science [2011-04-12] |
Scanning Tunneling Microscopy in Surface Science索书号:TH742.9/B786 Here, top international authors in the field of STM and surface science present first-class contributions on this hot topic, bringing the reader up to date with the latest developments in this rapidly advancing field. The focus is on the nanoscale, particularly in relation to catalysis, involving developments in our understanding of the nature of the surfaces of oxides and nanoparticulate materials, as well as adsorption, and includes in-situ studies of catalysis on such model materials. Preface.
List of Contributors. 1 Chirality at Metal Surfaces (Chris J. Baddeley and Neville V. Richardson). 1.1 Introduction. 1.2 Surface Chirality Following Molecular Adsorption. 1.3 Chiral Amplification and Recognition. 1.4 Conclusions. References. 2 The Template Route to Nanostructured Model Catalysts (Conrad Becker and Klaus Wandelt). 2.1 Introduction. 2.2 Surfaces as Two-Dimensional Templates. 2.3 STM Imaging of Oxide Films. 2.4 STM Imaging of Metal Particles on Oxide Films. 2.5 Template-Controlled Growth of Model Catalysts. 2.6 Conclusions. References. 3 In Situ STM Studies of Model Catalysts (Fan Yang and D. Wayne Goodman). 3.1 Introduction. 3.2 Instrumentation. 3.3 Visualizing the Pathway of Catalytic Reactions. 3.4 Metal Surfaces at High Pressures. 3.5 In Situ Studies of Supported Model Catalysts. 3.6 Outlook. References. 4 Theory of Scanning Tunneling Microscopy and Applications in Catalysis (Gilberto Teobaldi, Haiping Lin, and Werner Hofer). 4.1 Catalysis and Scanning Tunneling Microscopy. 4.2 Image Formation in an STM. 4.3 Simulating Tunneling Currents. 4.4 Simulating Chemical Reactivity. 4.5 Catalytic Water Production. 4.6 Outlook. References. 5 Characterization and Modification of Electrode Surfaces by In Situ STM (Dieter M. Kolb and Felice C. Simeone). 5.1 Introduction. 5.2 In Situ STM: Principle, Technical Realization and Limitations. 5.3 Imaging Single-Crystal Surfaces of Catalytically Relevant Systems. 5.4 Strategies for Nanostructuring Surfaces. References. 6 STM Imaging of Oxide Nanolayer Model Systems (Falko P. Netzer and Svetlozar Surnev). 6.1 Introduction. 6.2 Experimental Aspects and Technical Developments. 6.3 Case Studies: Selected Oxide–Metal Systems. 6.4 Synopsis and Outlook. References. 7 Surface Mobility of Atoms and Molecules Studied with High-Pressure Scanning Tunneling Microscopy (Gabor A. Somorjai, Feng Tao, and Derek Butcher). 7.1 Introduction. 7.2 Characterization of Surface Mobility of Molecules and Atoms. 7.3 High-Pressure STM Technique and Instrumentation. 7.4 Mobility and Flexibility of Catalyst Surfaces at High-Pressure High-Temperature Reaction Conditions. 7.5 Adsorbate Mobility During Catalytic Reactions. 7.6 Summary. References. 8 Point Defects on Rutile TiO2(1 1 0): Reactivity, Dynamics, and Tunability (Chi L. Pang and Geoff Thornton). 8.1 Introduction. 8.2 Methods. 8.3 Water Dissociation at Oxygen Vacancies and the Identification of Point Defects. 8.4 O2 Dissociation at Oxygen Vacancies. 8.5 Alcohol Dissociation at Oxygen Vacancies. 8.6 Diffusion of Oxygen Vacancies and Surface Hydroxy. 8.7 Tuning the Densities of Oxygen Vacancies and Surface Hydroxyl on TiO2(1 1 0). 8.8 Outlook. References. Index. |
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