A slip model for gas flows in micro/nano-channels induced by external body
forces is derived based on Maxwell's collision theory between gas molecules and
the wall. The model modifies the relationship between slip velocity and
velocity gradient at the walls by introducing a new parameter in addition to
the classic Tangential Momentum Accommodation Coefficient. Three-dimensional
Molecular Dynamics simulations of helium gas flows under uniform body force
field between copper flat walls with different channel height are used to
validate the model and to determine this new parameter

Bercegeay, C.

Bonnet, G.

Lauriat, G.

Leonard, C.

To, Q. D.

English

arXiv

International audienceA slip model for gas flows in micro/nanochannels induced by external body forces is derived based on Maxwell's collision theory between gas molecules and the wall. The model modifies the relationship between slip velocity and velocity gradient at the walls by introducing a new parameter in addition to the classic Tangential Momentum Accommodation Coefficient. Three-dimensional Molecular Dynamics simulations of helium gas flows under uniform body force field between copper flat walls with different channel height are used to validate the model and to determine this new parameter

To, Quy-Dong

Lauriat, Guy

Léonard, Céline

Bonnet, Guy

HAL Portal de Univ. Gustave Eiffel

A slip model for micro/nano gas flows induced by body forces

HAL - UPEC / UPEM

HAL: Hyper Article en Ligne

Archive Ouverte en Sciences de l'Information et de la Communication

Hal-Diderot

HAL Descartes

https://hal.science/hal-00714817v1/file/publi-2010-hal-00714817-to-al-microfluid-nanofluid.pdf

A slip model for micro/nano gas flows induced by body forces

Abstract

Similar works

Full text