Abstract:
Micro and nano scale semiconductor devices could undergo localized self-heating that obscures phonon transport and leads to size e ects and peak device temperatures. Consequently, device performance and lifetime are degraded. The pro le of the localized heating is the main contributor to the size e ects and a comprehensive numerical investigation is conducted for understanding pro le e ects. Also, besides numerical methods, accuracy of micro-Raman and thermore ectance thermal imaging (TTI) experiments for capturing the peak device temperature is investigated. It was observed that although the aspect ratio of heat generation area alters the size e ects, area was found as the main factor. Horizontal and vertical lengths of the pro le have dissimilar impact on the peak temperature. Moreover, heat ux boundary simpli cation is tested with sub-continuum model that could alleviate computational costs. If the heat generation pro le laterally spread, the phonon Boltzmann transport equation (BTE) model with boundary ux approximation can estimate the size e ects with 0.5- 8% errors. Also, this approximation yields 0.6-3.1% error in AlGaN/GaN transistor electro-thermal model. Virtual experiments showed that neither the micro-Raman nor the visible TTI can determine the peak temperature in AlGaN/GaN transistor and device structure does not change the accuracy markedly. TTI yields smaller error, nevertheless, it can be up to 21°C. Finally, these numerical calculations were proven by the actual visible TTI and the novel UV TTI experiments. The visible TTI experiment and continuum scale models underestimated the device peak temperature by 20°C. Furthermore, the agreement between the UV TTI method and the phonon BTE calculations proved the size e ects experimentally.
