Your search keyword '"Lacroix, David"' showing total 2 results

1. Prediction of the thermal conductivity anisotropy of Si nanofilms. Results of several numerical methods

Author

Terris, Damian, Joulain, Karl, Lemonnier, Denis, Lacroix, David, and Chantrenne, Patrice

Subjects

*PROPERTIES of matter, *MECHANICS (Physics), *DIFFUSION, *ANISOTROPY

Abstract

Abstract: The purpose of this work is to predict the in-plane and cross-plane thermal properties of crystalline silicon films. Several thicknesses from 20 nm to 6 μm and mean temperatures between 20 and 500 K have been investigated. Heat transport properties in silicon films have been studied through three different techniques: a semi-analytical method based upon the Kinetic Theory, a deterministic solution of the Boltzmann Transfer Equation (BTE) through the Discrete Ordinate Method and a statistical handling of the BTE by means of Monte Carlo Method. Each technique requires a model for the bulk material dispersion curves and the collision times of the different scattering processes. The three techniques have been validated through their correct prediction of silicon bulk thermal conductivity. Comparisons with in-plane thermal conductivity calculations and measurements have been also discussed. Thus, the cross-plane thermal conduction properties have been predicted. The expected temperature and thickness variations of the thermal conduction properties have been observed: the cross-plane thermal conduction appears to be less efficient than the in-plane thermal conduction, which proves that a significant anisotropy exists. [Copyright &y& Elsevier]

Published

2009

2. Transient combined radiation and conduction heat transfer in fibrous media with temperature and flux boundary conditions

Author

Asllanaj, Fatmir, Jeandel, Gérard, Roche, Jean Rodolphe, and Lacroix, David

Subjects

*HEAT conduction, *HEAT transfer, *BOUNDARY value problems, *QUANTUM optics

Abstract

Transient radiative and conductive heat transfer in a fibrous medium with anisotropic optical properties is investigated. Two different kinds of boundary conditions are treated: when the temperatures imposed on the boundaries vary with time and when the medium is subject to a radiation source which varies with time. A one dimensional case is considered. The non-linear transient Heat Conduction Equation is solved using the Kirchhoff transformation associated with a P2 finite elements method using a non-uniform spatial mesh. The Radiative Transfer Equation is solved using a direct method which is analytical in space whereas the spectral scattering and absorption coefficients as well as the phase function are determined using the Mie theory. This procedure is applied on the whole time domain. Finally, a realistic application to a fibrous insulation composed of silica fibers is treated numerically. [Copyright &y& Elsevier]

Published

2004