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Quantum size effects in metal particles
W. P. Halperin
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Corresponding author for this work
Physics and Astronomy
Research output
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Contribution to journal
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Article
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peer-review
1273
Scopus citations
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Keyphrases
Metal Particles
100%
Quantum Electronics
100%
Electronic Effect
100%
Quantum Size Effect
100%
Preparation Method
50%
Comprehensive Evaluation
50%
Spin-orbit Coupling
50%
Adsorbate
50%
Correlation Function
50%
Function-based
50%
Infrared Absorption
50%
Nuclear Magnetic Resonance
50%
Particle Properties
50%
Matrix Composites
50%
Distribution Function
50%
Optical Absorption
50%
Size Effect
50%
Random Matrix Theory
50%
Magnetic Susceptibility
50%
Fundamental Symmetries
50%
Matrix Effect
50%
Heat Capacity
50%
Magnetic Field Dependence
50%
Particle Cluster
50%
Electronic Spectra
50%
Level Distribution
50%
Electron Spin Resonance
50%
Absorption Measurement
50%
Knight Shift
50%
Metallic Particles
50%
Quantum Effects
50%
Reduced Volume
50%
Metallic Clusters
50%
Particle Preparation
50%
Far-infrared Absorption
50%
Cluster Beam Technique
50%
Physics
Metal Particle
100%
Quantum Electronics
100%
Nuclear Magnetic Resonance
100%
Infrared Absorption
100%
Nuclear Magnetic Resonance
100%
Quantum Size Effect
100%
Distribution Function
50%
Spin-Orbit Interaction
50%
Electronic Spectrum
50%
Magnetic Field
50%
Electromagnetic Absorption
50%
Electron Paramagnetic Resonance
50%
Magnetic Permeability
50%
Specific Heat
50%
Engineering
Size Effect
100%
Infrared Absorption
66%
Electron Level
66%
Experimental Work
33%
Level Distribution
33%
Absorption Measurement
33%
Quantum Effect
33%
Adsorbate
33%
Magnetic Field
33%
Nuclear Magnetic Resonance
33%
Matrix Theory
33%
Heat Capacity
33%
Matrix Effect
33%
Absorptivity
33%
Magnetic Permeability
33%
Material Science
Nuclear Magnetic Resonance
100%
Adsorbate
33%
Particle Property
33%
Matrix Composite
33%
Magnetic Susceptibility
33%
Electron Paramagnetic Resonance Spectroscopy
33%
Particle Preparation
33%
Surface (Surface Science)
33%
Chemical Engineering
Specific Heat
100%