Microscale gas flow : a comparison of Grad's 13 moment equations and other continuum approaches

Thatcher, Toby

10 April 2008

Advances in manufacturing techniques over the last decade have made it possible to make electrical devices with dimensions as small as 90 nanometers [I]. Using similar techniques, devices that perform moving mechanical tasks less than 100 pm are being manufactured in quantity [2] [3], e.g., pumps, turbines, valves and nozzles. These devices are incorporated into microelectromechanical systems (MEMS) that can be potentially used in devices such as medical and chemical sensors, and fuel cells. The gas and fluid flows in devices of this size exhibit behavior that can not be described by the classical Navier-Stokes and Fourier equations of continuum mechanics. This happens when flows become rarefied such that the mean free path (distance between two subsequent particle collisions) is not negligible compared to the characteristic length scale. The rarefaction of a fluid flow is also seen in the upper atmosphere for larger length scales, e.g., for re-entry for space craft and some supersonic jet aircraft. Currently, when one looks to model fluid flow and heat transfer in a rarefied flow there are two predominantly accepted choices. Either one uses jump and slip boundary conditions with the Navier-Stokes and Fourier (NSF) equations, or a statistical particle model such as direct simulation Monte-Carlo (DSMC) [4] and the Boltzmann equation. DSMC is computationally intensive for complex flows and the NSF solutions are only valid for low degrees of rarefaction. As an alternative to these methods we have used Grad's 13 moment expansion of the Boltzmann equation [5]. For its implementation, a set of boundary conditions and three numerical methods for the solution have been devised. The model is applied to the solution of 2-D micro Couette flow with heat transfer. Results are compared to those obtained from the Navier-Stokes-Fourier equations, reduced Burnett equations, Regularized 13 moment equations and DSMC simulations.

Gas flow

The application of the hydraulic analogies to problems of two-dimensional compressible gas flow

Hatch, John Elmer

05 1900

No description available.

Gas flow

Mass, heat and momentum transfer in the flow of gases through granular solids

Gamson, Bernard William.

January 1943

Thesis (Ph. D.)--University of Wisconsin--Madison, 1943. / Typescript. Vita. Includes bibliographical references (leaves 171-174).

Gas flow.

The accuracy of the orifice in measuring small flows of gas

Venn, Rollo Evenas.

January 1934

Call number: LD2668 .T4 1934 V41

Gas flow.

Masters theses

Field study of roof-top atmospheric turbulence and gas dispersion in urban area

林嘉仕, Lam, Ka-se.

January 1992

published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy

Atmospheric turbulence.

Gas flow.

Flow through packed beds at sub-atmospheric pressure

Igwe, G. J. I.

January 1983

No description available.

660

Gas flow rate

Further studies of unsteady gas flow in the manifolds of multi-cylinder automobile engines

Blair, Alan John

January 1986

No description available.

532

Gas flow in engines

Gas dispersion and atmospheric turbulence on the roof top of a medium rise building /

Lam, Ka-se.

January 1984

Thesis--M. Phil., University of Hong Kong, 1984.

Gas flow. Atmospheric turbulence.

Gas dispersion and atmospheric turbulence on the roof top of a medium rise building

林嘉仕, Lam, Ka-se.

January 1984

published_or_final_version / Mechanical Engineering / Master / Master of Philosophy

Gas flow.

Atmospheric turbulence.

ISOTHERMAL BUBBLE MOTION UNDER THE INFLUENCE OF VARYING BODY FORCES

Schrage, Dale Leonard, 1944-

January 1970

No description available.

Bubbles.

Gas flow.