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Excess electron surface states on helium clusters
M. Rosenblit
*
,
Joshua Jortner
*
Corresponding author for this work
School of Chemistry
Tel Aviv University
Research output
:
Contribution to journal
›
Article
›
peer-review
21
Scopus citations
Overview
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Keyphrases
Algebraic Relations
16%
Charge Distribution
16%
Cluster Size
100%
Critical Cluster
16%
Critical Radius
16%
Dielectric
16%
Electric Field Effect
16%
Electron Localization
33%
Electron States
16%
Electronic Energy
33%
Electronic Excitation
16%
Electronic Spectroscopy
16%
Electronic States
50%
Electronic Surface States
16%
Electronic Transitions
16%
Energy Strength
16%
Excess Electron
100%
Field-induced
16%
Flat Surface
16%
Helium Clusters
100%
Hydrogen Atom
16%
Image Potential
16%
Micro-surfacing
16%
Model Potential
33%
N-Cluster
16%
Oscillator Strength
33%
Polarizability
33%
Pseudopotential
16%
Quantitative Characterization
16%
Quantum Mechanical Calculations
16%
Repulsive Interaction
16%
Scaling Relations
16%
Size Dependence
50%
Surface Size
16%
Surface States
100%
Transition Energy
33%
Chemistry
Charge Distribution
33%
Dielectric Material
33%
Electric Field Effect
33%
Electron Localization
66%
Electronic Excitation
33%
Electronic Spectroscopy
33%
Electronic State
100%
Electronic Transition
33%
electronics
100%
Helium
100%
Hydrogen Atom
33%
Oscillator Strength
66%
Polarizability
66%
Pseudopotential
33%
Surface State
100%
Engineering
Bridging
33%
Cluster Size
100%
Critical Cluster Radius
33%
Critical Radius
33%
Dielectrics
33%
Domain Size
33%
Electric Field
33%
Electronic Excitation
33%
Electronic State
100%
Energy Transition
66%
Flat Surface
33%
Oscillator
66%
Polarizability
66%
Repulsive Interaction
33%
Surface State
100%
Material Science
Dielectric Material
25%
Oscillator
50%
Surface (Surface Science)
100%