Heat generation in integrated circuits

Template:Wikify is deprecated. Please use a more specific cleanup template as listed in the documentation.

The template {{Expand}} has been deprecated since 26 December 2010, and is retained only for old revisions. If this page is a current revision, please remove the template.

This article needs attention from an expert in Electronics. Please add a reason or a talk parameter to this template to explain the issue with the article. WikiProject Electronics may be able to help recruit an expert. (March 2009)

The heat dissipation in integrated circuits problem has gained an increasing interest in recent years due to the miniaturization of semiconductor devices. The temperature increase becomes relevant for cases of relatively small-cross-sections wires, because such temperature increase may affect the normal behavior of semiconductor devices.

Joule Heating is a predominant heat mechanism for heat generation in integrated circuits ^[1] and is an undesired effect.

The governing equation of the physics of the problem to be analyzed is the heat diffusion equation. It relates the flux of heat in space, its variation in time and the generation of power.

${\displaystyle \nabla \left(\kappa \nabla T\right)+g=\rho C{\frac {\partial T}{\partial t}}}$

Where ${\displaystyle \kappa }$ is the thermal conductivity, ${\displaystyle \rho }$ is the density of the medium, ${\displaystyle C}$ is the specific heat

${\displaystyle k={\frac {\kappa }{\rho C}}\,}$

the thermal diffusivity and g is the rate of heat generation per unit volume. Heat diffuses from the source following equation ([eq:diffusion]) and solution in an homogeneous medium of ([eq:diffusion]) has a Gaussian distribution.

• Thermal simulations for Integrated Circuits