Title :
Heat Conduction in Microwave Devices With Orthotropic and Temperature-Dependent Thermal Conductivity
Author_Institution :
MS2, Lockheed Martin, Moorestown, NJ
fDate :
3/1/2007 12:00:00 AM
Abstract :
This paper deals with steady-state heat conduction in integrated circuits due to surface heating. Temperature-dependent and orthotropic thermal conductivities are assumed, and an exact formula is obtained for the temperature field in the integrated circuit due to arbitrary surface flux loading. These general results are then specialized to specific forms of surface flux representative of multifingered FETs of arbitrary gate length, gatewidth, and pitch. Numerical results are presented for a representative transistor on a gallium-arsenide substrate and comparisons are made, where possible, to existing approximate solutions, as well as to finite-element results. The examples are chosen to highlight the effects of orthotropy and temperature dependence of thermal conductivity on the junction temperature of devices on integrated circuits
Keywords :
III-V semiconductors; field effect transistors; gallium arsenide; heat conduction; microwave devices; thermal conductivity; thermal variables measurement; Fourier series; arbitrary surface flux loading; gallium-arsenide substrate; integrated circuits; junction temperature; microwave devices; multifingered FET; orthotropic thermal conductivity; representative transistor; steady-state heat conduction; surface heating; temperature field; temperature-dependent thermal conductivity; Degradation; Electromagnetic heating; Finite element methods; Heat treatment; Microwave FET integrated circuits; Microwave FETs; Microwave devices; Temperature dependence; Temperature distribution; Thermal conductivity; Fourier series; orthotropic; temperature dependent; transistor;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2006.890526
