Transport Phenomena of Water in Molecular Fluidic Channels

In molecular-level fluidic transport, where the discrete characteristics of a molecular system are not negligible (in contrast to a continuum description), the response of the molecular water system might still be similar to the continuum description if the time and ensemble averages satisfy the erg...

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Bibliographic Details
Published in:Scientific reports 2016-09, Vol.6 (1), p.33881-33881, Article 33881
Main Authors: Vo, Truong Quoc, Kim, BoHung
Format: Article
Language:English
Subjects:
639/766/189
639/925/929/115
Boundary conditions
Humanities and Social Sciences
Hypotheses
Interfaces
Mathematical models
multidisciplinary
Science
Velocity
Viscosity
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Summary:In molecular-level fluidic transport, where the discrete characteristics of a molecular system are not negligible (in contrast to a continuum description), the response of the molecular water system might still be similar to the continuum description if the time and ensemble averages satisfy the ergodic hypothesis and the scale of the average is enough to recover the classical thermodynamic properties. However, even in such cases, the continuum description breaks down on the material interfaces. In short, molecular-level liquid flows exhibit substantially different physics from classical fluid transport theories because of (i) the interface/surface force field, (ii) thermal/velocity slip, (iii) the discreteness of fluid molecules at the interface and (iv) local viscosity. Therefore, in this study, we present the result of our investigations using molecular dynamics (MD) simulations with continuum-based energy equations and check the validity and limitations of the continuum hypothesis. Our study shows that when the continuum description is subjected to the proper treatment of the interface effects via modified boundary conditions, the so-called continuum-based modified-analytical solutions, they can adequately predict nanoscale fluid transport phenomena. The findings in this work have broad effects in overcoming current limitations in modeling/predicting the fluid behaviors of molecular fluidic devices.
ISSN:2045-2322
2045-2322
DOI:10.1038/srep33881