Molecular simulation of steady-state evaporation and condensation: Validity of the Schrage relationships

The accuracy, or even the validity, of the Schrage relationships expressing the rate of evaporation and condensation in terms of local interfacial thermodynamics properties and the mass accommodation coefficient is a subject of significant discussion. In this work, we carry out molecular dynamics (M...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2017-11, Vol.114, p.105-114
Main Authors: Liang, Zhi, Biben, Thierry, Keblinski, Pawel
Format: Article
Language:English
Subjects:
Accommodation coefficient
Chemical Sciences
Condensation
Energy conservation
Engineering Sciences
Evaporation
Evaporation rate
Fluxes
Liquid surfaces
Molecular dynamics
Physics
Simulation
Steady state
Temperature
Thermodynamics
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Summary:The accuracy, or even the validity, of the Schrage relationships expressing the rate of evaporation and condensation in terms of local interfacial thermodynamics properties and the mass accommodation coefficient is a subject of significant discussion. In this work, we carry out molecular dynamics (MD) simulations of evaporation and condensation of fluid Ar in a nanochannel. By adjusting the temperature difference, ΔT, between the evaporating and condensing surfaces, we control the steady-state evaporation and condensation fluxes (JMD). We find that across a wide ΔT range studied, JMD is always in excellent agreement with the prediction from the exact Schrage relationships. Furthermore, if the temperature difference between the two liquid surfaces in the nanochannel is less than ∼20% of the average absolute temperature, we find that both energy and mass fluxes at the interface are proportional to ΔT. Our analysis indicates that in the case of steady-state evaporation and condensation processes, the exact Schrage relationships satisfy the conservation of mass, momentum and energy, and provides accurate predictions of the rates of the associated processes.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2017.06.025