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Multilayer relaxation of Cu(331)
W. T. Geng, A. J. Freeman
Physics and Astronomy
Research output
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Contribution to journal
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Article
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peer-review
20
Scopus citations
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Dive into the research topics of 'Multilayer relaxation of Cu(331)'. Together they form a unique fingerprint.
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Keyphrases
Monolayer Relaxation
100%
Atomic Layers
66%
Low Energy Electron Diffraction
66%
Terraces
66%
First-principles
33%
Prediction Method
33%
Generalized Gradient Approximation
33%
Diffraction Measurements
33%
Bond Length
33%
Full-potential Linearized Augmented Plane Wave Method
33%
Bond Order
33%
Electron Diffraction Analysis
33%
Embedded Atom Method
33%
Anomalous Behavior
33%
Interlayer Spacing
33%
Electronic Structure Analysis
33%
Transition Metal Surfaces
33%
Cu(211)
33%
Chemistry
Relaxation
100%
Multilayer
100%
Low Energy Electron Diffraction
66%
Bond Length
33%
Electronic State
33%
Generalized Gradient Approximation
33%
First Principle
33%
Augmented Plane Wave Method
33%
Bond Order
33%
Transition Metal
33%
Physics
Electron Diffraction
100%
First-Principles
50%
Transition Metal
50%
Plane Wave
50%
Generalized Gradient Approximation
50%
Energy Levels
50%
Metal Surface
50%
Embedded Atom Method
50%
Material Science
Low-Energy Electron Diffraction
100%
Transition Metal
50%
Metal Surface
50%
Diffraction Measurement
50%
Surface (Surface Science)
50%
Energy Levels
50%