Study of non-diffusive thermal behaviors in nanoscale transistors under different heating strategies

Chuang Zhang, Ziyang Xin, Qin Lou, Hong Liang

Published 2024-08-15Version 1

Understanding the phonon transport mechanisms and efficiently capturing the spatiotemporal distributions of temperature is of great significance for alleviating hotspot issues in the electronic devices. Most previous simulations mainly focused on the steady-state problem with continuous heating, and the effective Fourier's law (EFL) is widely used for practical multiscale thermal engineering due to its simplicity and efficiency although it still follows the diffusive rule. However, non-continuous heating is more common in the electronic devices, and few comparative study is conducted to estimate how much deviation the EFL would produce. To answer above questions, the heat conduction in nanoscale bulk or silicon-on-insulator (SOI) transistors is investigated by the phonon Boltzmann transport equation (BTE) under three heating strategies, namely, `Continuous', `Intermittent' and `Alternating' heating. Numerical results in the quasi-2D or 3D hotspot systems show that it is not easy to accurately capture the micro/nano scale heat conduction by the EFL, especially near the hotspot regions. Different heating strategies have great influence on the temperature rise and transient thermal dissipation process. Compared to `Intermittent' heating, the temperature variance of `Alternating' heating is smaller.