Scanning Tunneling Microscopy III [E-Book] : Theory of STM and Related Scanning Probe Methods / edited by Roland Wiesendanger, Hans-Joachim Güntherodt.
While the first two volumes on Scanning Tunneling Microscopy (STM) and its related scanning probe (SXM) methods have mainly concentrated on intro ducing the experimental techniques, as well as their various applications in different research fields, this third volume is exclusively devoted to the t...
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Full text |
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Personal Name(s): | Güntherodt, Hans-Joachim, editor |
Wiesendanger, Roland, editor | |
Imprint: |
Berlin, Heidelberg :
Springer,
1993
|
Physical Description: |
XV, 375 p. online resource. |
Note: |
englisch |
ISBN: |
9783642974700 |
DOI: |
10.1007/978-3-642-97470-0 |
Series Title: |
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Springer Series in Surface Sciences ;
29 |
Subject (LOC): |
- 1. Introduction
- 1.1 Theoretical Concepts for Scanning Tunneling Microscopy
- 1.2 Theoretical Concepts for Force Microscopy
- References
- 2. STM Imaging of Single-Atom Adsorbates on Metals
- 2.1 Tunneling Hamiltonian Approach
- 2.2 Adsorbates on Metal Surfaces
- 2.3 Close Approach of the Tip: The Strong-Coupling Regime
- References
- 3. The Scattering Theoretical Approach to the Scanning Tunneling Microscope
- 3.1 The Theoretical Formalism
- 3.2 Tunneling Through Thick Organic Layers
- 3.3 Scanning Tunneling Microscopy at Metal Surface
- 3.4 Summary and Conclusions
- References
- 4. Spectroscopic Information in Scanning Tunneling Microscopy
- 4.1 Green’s Function Method
- 4.2 Derivation of the Transfer Hamiltonian Approach
- 4.3 One-Dimensional Models
- 4.4 Three-Dimensional Models
- 4.5 Conclusion
- References
- 5. The Role of Tip Atomic and Electronic Structure in Scanning Tunneling Microscopy and Spectroscopy
- 5.1 Background
- 5.2 Formalism of Theoretical Simulation of STM/STS
- 5.3 Simulation of STM/STS of the Graphite Surface
- 5.4 STM/STS of Si(100) Reconstructed Surfaces
- 5.5 The Negative-Differential Resistance Observed on the $$ Si\left( {111} \right)\sqrt 3 \, \times \,\sqrt 3 - B $$ Surface
- 5.6 The STM Image of the $$ Si\left( {111} \right)\sqrt 3 \, \times \,\sqrt 3 - Ag $$ Surface and the Effect of the Tip
- 5.7 Light Emission from a Scanning Tunneling Microscope
- 5.8 Summary and Future Problems
- Note Added in Proof
- References
- 6. Bohm Trajectories and the Tunneling Time Problem
- 6.1 Background
- 6.2 A Brief Discussion of Previous Approaches
- 6.3 Bohm’s Trajectory Interpretation of Quantum Mechanics
- 6.4 Application to Simple Systems
- 6.5 Discussion
- References
- Additional References with Titles
- 7. Unified Perturbation Theory for STM and SFM
- 7.1 Background
- 7.2 The Modified Bardeen Approach
- 7.3 Explicit Expressions for Tunneling Matrix Elements
- 7.4 Theoretical STM Images
- 7.5 Effect of Atomic Forces in STM Imaging
- 7.6 In-Situ Characterization of Tip Electronic Structure
- 7.7 Summary
- 7.8 Appendix: Modified Bardeen Integral for the Hydrogen Molecular Ion
- References
- 8. Theory of Tip—Sample Interactions
- 8.1 Tip—Sample Interaction
- 8.2 Long-Range (Van der Waals) Forces
- 8.3 Interaction Energy: Adhesion
- 8.4 Short-Range Forces
- 8.5 Deformations
- 8.6 Atom Transfer
- 8.7 Tip-Induced Modifications of Electronic Structure
- 8.8 Calculation of Current at Small Separation
- 8.9 Constriction Effect
- 8.10 Transition from Tunneling to Ballistic Transport
- 8.11 Tip Force and Conductivity
- 8.12 Summary
- References
- 9. Consequences of Tip—Sample Interactions
- 9.1 Methodology
- 9.2 Case Studies
- References
- 10. Theory of Contact Force Microscopy on Elastic Media
- 10.1 Description of a Scanning Force Microscope
- 10.2 Elastic Properties of Surfaces
- 10.3 Interaction Between SFM and Elastic Media
- 10.4 Conclusions and Outlook
- References
- 11. Theory of Atomic-Scale Friction
- 11.1 Microscopic Origins of Friction
- 11.2 Ideal Friction Machines
- 11.3 Predictive Calculations of the Friction Force
- 11.4 Limits of Non-destructive Tip—Substrate Interactions in Scanning Force Microscopy
- References
- 12. Theory of Non-contact Force Microscopy
- 12.1 Methodical Outline
- 12.2 Van der Waals Forces
- 12.3 Ionic Forces
- 12.4 Squeezing of Individual Molecules: Solvation Forces
- 12.5 Capillary Forces
- 12.6 Conclusions
- References.