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Capillarity theory for the "coexistence" of liquid and solid clusters
H. Reiss, P. Mirabel, R. L. Whetten
Research output
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Contribution to journal
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Article
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peer-review
186
Scopus citations
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Keyphrases
Capillarity Theory
100%
Simple Theory
100%
Liquid Cluster
100%
Melting Temperature
66%
Vapor Pressure
66%
Thermodynamic Parameters
66%
Transition Rates
66%
Lower Limit
33%
From below
33%
Thermodynamics
33%
Argon
33%
Surface Tension
33%
Molecular Simulation
33%
Cluster Size
33%
Magic numbers
33%
Molecular Theory
33%
Capillarity Phenomena
33%
Supercooling
33%
Free Energy Barrier
33%
Heat of Fusion
33%
Metastable Equilibrium
33%
Argon Jet
33%
Engineering
Melting Temperature
100%
Thermodynamic Parameter
100%
Capillarity
100%
Lower Limit
50%
Good Agreement
50%
Upper Limit
50%
Surface Density
50%
Cluster Size
50%
Energy Barrier
50%
Tension Surface
50%
Melting Point
50%
Metastable Equilibrium
50%
Chemistry
Melting Point
100%
Capillarity
100%
Argon
66%
Vapor Pressure
66%
Energy Barrier
33%
Gibbs Free Energy
33%
Jet
33%
Nucleation
33%
Rate of Transition
33%
Supercooling
33%
Physics
Melting Point
100%
Capillarity
100%
Free Energy
33%
Nucleation
33%
Supercooling
33%
Density Parameters
33%
Heat of Fusion
33%
Material Science
Capillarity
100%
Density
50%
Nucleation
50%
Surface Tension
50%
Chemical Engineering
Gibbs Free Energy
100%
Supercooling
100%