Title :
Multiscale Electrothermal Modeling of Nanostructured Devices
Author :
Romano, Giuseppe ; Carlo, Aldo Di
Author_Institution :
Dept. of Electron. Eng., Univ. of Rome Tor Vergata, Rome, Italy
Abstract :
In this study, we develop an electro-thermal model to investigate heating and heat dissipation in nanostructured devices. The heating is computed by a drift-diffusion simulation, which accounts for the dissipative transport of charge carriers. The heat dissipation model is based on the phonon Boltzmann transport equation (PBTE). Application of the electrothermal model to a truncated-pyramid-shaped GaN dot embedded in an AlGaN nanocolumn reveals the existence of mesoscopic effects such as a hotspot across the quantum dot and thermal boundary resistances. We enhance the computational efficiency of the thermal model by implementing a coupled PBTE/Fourier model. This method, based on the domain partitioning, provides the same maximum temperature as that computed by the simple PBTE model, resulting, therefore, a powerful scheme for capture local heating effect with relatively low computational effort. Details about the numerical implementation are also provided.
Keywords :
Boltzmann equation; Fourier analysis; III-V semiconductors; aluminium compounds; cooling; diffusion; gallium compounds; light emitting diodes; phonons; semiconductor quantum dots; thermal conductivity; wide band gap semiconductors; Fourier model; GaN-AlGaN; charge carriers; computational efficiency; dissipative transport; domain partitioning; drift-diffusion simulation; heat dissipation; local heating effect; mesoscopic effects; multiscale electrothermal modeling; nanostructured device; phonon Boltzmann transport equation; thermal boundary resistance; truncated-pyramid-shaped dot; Computational modeling; Conductivity; Heating; Mathematical model; Phonons; Thermal conductivity; Device; hotspot; multiscale; nanostructure; thermal;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2011.2129574
