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Thermal capillary waves relaxing on atomically thin liquid films
A. M. Willis,
J. B. Freund
Aerospace Engineering
Mechanical Science and Engineering
Coordinated Science Lab
National Center for Supercomputing Applications (NCSA)
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Keyphrases
Atomistic Simulation
100%
Thin Liquid Film
100%
Lennard-Jones
100%
Atomically Thin
100%
Thermal Capillary Waves
100%
Long Wavelength
50%
Continuum Model
50%
Surface Viscosity
50%
In Films
50%
Decay Rate
50%
Power Law
50%
Molecular Scale
50%
Atomic Scale
50%
Surface Tension
50%
Relaxation Dynamics
50%
Radius of Gyration
50%
Solid Wall
50%
Scale Effect
50%
Liquid Film
50%
Intermediate Regime
50%
Wave number
50%
No-slip Boundary Condition
50%
Continuum Description
50%
Shortwave
50%
Range Collapse
50%
Wave Decay
50%
Length Scale Parameter
50%
Capillary Waves
50%
Engineering
Atomistic Simulation
100%
Liquid Films
100%
Length Scale
50%
Continuum Model
50%
Fluid Viscosity
50%
Assuming
50%
Radius of Gyration
50%
Molecular Scale
50%
Tension Surface
50%
Scale Effect
50%
Solid Wall
50%
No-Slip Boundary Condition
50%
Scale Parameter
50%
Material Science
Film
100%
Thin Liquid Film
100%
Surface Tension
100%
Liquid Films
100%
Physics
Capillary Wave
100%
Lennard-Jones
66%
Boundary Condition
33%
Relaxation (Mechanics)
33%
Scale Effect
33%
Earth and Planetary Sciences
Capillary Wave
100%
Power Law
33%
Boundary Condition
33%
Decay Rate
33%
Scale Effect
33%
Relaxation (Mechanics)
33%