|  | Bowker, Michael / Davies, Philip R. (eds.)
Scanning Tunneling Microscopy in Surface Science
 1. Edition December 2009
122.- Euro
2009. XIV, 244 Pages, Hardcover
159 Fig. (69 Colored Fig.)
- Monograph -
ISBN 978-3-527-31982-4 - Wiley-VCH, Weinheim
|
Content
Sample Chapter
Erratum Chapter 5
| Buy now 
E-Books are also available on all known E-Book shops.
|
| Short description
Top international authors present first-class contributions on this hot topic, detailing STM applications for practitioners in surface science, as well as scientists working in nanotechnology, catalysis, and polymer chemistry.
From the contents
Preface
CHIRALITY AT METAL SURFACES
Introduction
Surface Chirality Following Molecular Adsorption
Chiral Amplification and Recognition
Conclusions
THE TEMPLATE TO NANOSTRUCTURED MODEL CATALYSTS
Introduction
Surfaces as Two-Dimensional Templates
STM Imaging of Oxide Films
STM Imaging of Metal Particles on Oxide Films
Template-Controlled Growth of Model Catalysts
Conclusions
IN SITU STM STUDIES OF MODEL CATALYSTS
Introduction
Instrumentation
Visualizing the Pathway of Catalytic Reactions
Metal Surfaces at High Pressures
In Situ Studies of Supported Model Catalysts
Outlook
THEORY OF SCANNING TUNNELING MICROSCOPY AND APPLICATIONS IN CATALYSIS
Catalysis and Scanning Tunneling Microscopy
Image Formation in an STM
Simulating Tunneling Currents
Simulating Chemical Reactivity
Catalytic Water Production
Outlook
CHARACTERIZATION AND MODIFICATION OF ELECTRODE SURFACES BY IN SITU STM
Introduction
In Situ STM: Principle, Technical Realization and Limitations
Imaging Simple-Crystal Surfaces of Catalytically Relevant Systems
Strategies for Nanostructuring Surfaces
STM IMAGING OF OXIDE NANOLAYER MODEL SYSTEMS
Introduction
Experimental Aspects and Technical Developments
Case Studies: Selected Oxide-Metal Systems
Synopsis and Outlook
SURFACE MOBILITY OF ATOMS AND MOLECULES STUDIED WITH HIGH-PRESSURE SCANNING TUNNELING MICROSCOPY
Introduction
Characterization of Surface Mobility of Molecules and Atoms
High-Pressure STM Technique and Instrumentation
Mobility and Flexibility of Catalyst Surfaces at High-Pressure
Adsorbate Mobility During Catalytic Reactions
Summary
POINT DEFECTS ON RUTILE TiO2(1 1 0): REACTIVITY, DYNAMICS, AND TUNABILITY
Introduction
Methods
Water Dissociation at Oxygen Vacancies and the Identification of Point Defects
O2 Dissociation at Oxygen Vacancies
Diffusion of Oxygen Vacancies and Surface Hydroxy
Tuning the Densities of Oxygen Vacancies and Surface Hydroxyl on TiO2(1 1 0)
Outlook
|
|
|
|
