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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. Of high interest to practitioners of surface science, nanoscience, STM and catalysis.
Inhaltsverzeichnis
PrefaceCHIRALITY AT METAL SURFACESIntroductionSurface Chirality Following Molecular AdsorptionChiral Amplification and RecognitionConclusionsTHE TEMPLATE TO NANOSTRUCTURED MODEL CATALYSTSIntroductionSurfaces as Two-Dimensional TemplatesSTM Imaging of Oxide FilmsSTM Imaging of Metal Particles on Oxide FilmsTemplate-Controlled Growth of Model CatalystsConclusionsIN SITU STM STUDIES OF MODEL CATALYSTSIntroductionInstrumentationVisualizing the Pathway of Catalytic ReactionsMetal Surfaces at High PressuresIn Situ Studies of Supported Model CatalystsOutlookTHEORY OF SCANNING TUNNELING MICROSCOPY AND APPLICATIONS IN CATALYSISCatalysis and Scanning Tunneling MicroscopyImage Formation in an STMSimulating Tunneling CurrentsSimulating Chemical ReactivityCatalytic Water ProductionOutlookCHARACTERIZATION AND MODIFICATION OF ELECTRODE SURFACES BY IN SITU STMIntroductionIn Situ STM: Principle, Technical Realization and LimitationsImaging Simple-Crystal Surfaces of Catalytically Relevant SystemsStrategies for Nanostructuring SurfacesSTM IMAGING OF OXIDE NANOLAYER MODEL SYSTEMSIntroductionExperimental Aspects and Technical DevelopmentsCase Studies: Selected Oxide-Metal SystemsSynopsis and OutlookSURFACE MOBILITY OF ATOMS AND MOLECULES STUDIED WITH HIGH-PRESSURE SCANNING TUNNELING MICROSCOPYIntroductionCharacterization of Surface Mobility of Molecules and AtomsHigh-Pressure STM Technique and InstrumentationMobility and Flexibility of Catalyst Surfaces at High-PressureAdsorbate Mobility During Catalytic ReactionsSummaryPOINT DEFECTS ON RUTILE TiO2(1 1 0): REACTIVITY, DYNAMICS, AND TUNABILITYIntroductionMethodsWater Dissociation at Oxygen Vacancies and the Identification of Point DefectsO2 Dissociation at Oxygen VacanciesDiffusion of Oxygen Vacancies and Surface HydroxyTuning the Densities of Oxygen Vacancies and Surface Hydroxyl on TiO2(1 1 0)Outlook
Über den Autor / die Autorin
Michael Bowker has worked in surface science and catalysis for the last 25 years and has approximately 250 publications. He has worked in both industry (ICI) and academia. He leads the Heterogeneous Catalysis and Surface Science group in Cardiff, consisting of nine academic members of staff and 70 researchers. He founded the Wolfson Nanoscience Laboratory at Cardiff in 2006 and is Deputy Director of the recently established Cardiff Catalysis Institute. His research has focused on adsorption and surface reactivity, ranging from theo-retical studies of the effect of sintering, to selective oxidation catalysis, to studies of adsorption on well-defined surfaces. He has used STM for 20 years to study various aspects of surface structure and reactivity, pioneering the use of high temperature STM in this field. The group continues to focus on aspects of surface science and catalysis, now extending to nanoengineering and bio-surface interactions.
Philip R. Davies studied chemistry and mathematics in Southampton University. Undergraduate projects on surface electrochemistry with Prof. Laurence Peter and the modelling of adsorption at fractal surfaces with Professor Dominic Tildesley stopped him from becoming an accountant and led to his interest in surface processes. After graduating with double honours in 1986, he moved to Cardiff to study reactions at surfaces with surface-sensitive spectroscopy under the supervision of Prof. Wyn Roberts. After being awarded a PhD, he was appointed to a lectureship in the Department of Chemistry at Cardiff and continued to study surface reaction mechanisms and particularly the role of short lived intermediates. Since 1997, his interests have centred largely on the influence of local atomic structure on reaction mechanisms studied with scanning probe microscopies.
Zusammenfassung
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.
Of high interest to practitioners of surface science, nanoscience, STM and catalysis.
Bericht
"The book covers a wide range of aspects of STM studies on catalysis: methodology, instrumentation, experiment, and theory. An index at the end of the book enables readers to promptly locate the content of their interests. The book contains numerous high-resolution STM images, which renders a pleasant reading experience as well as stimulates appreciation of the power of STM. Therefore, I highly recommend that this book have a space on your bookshelf." ( Microscopy and Microanalysis , February 2011)
"A very useful addition to your bookshelf . . . Whether you read only the one chapter related to your area or the entire book . . ., you are bound to learn something new about this unique instrument and its continued impact on nearly every aspect of surface science and nanoscience as well as its ever-increasing contributions toward understanding catalysis." ( JACS , 2010)
