Despite otherwise advantageous properties, the performance and reliability of devices manufactured in ß-Ga2O3 on semi-insulating Ga2O3 substrates may degrade because of poorly mitigated self-heating, which results from the low thermal conductivity of Ga2O3 substrates. In this work, we investigate and compare self-heating and device performance of β-Ga2O3 MESFETs on substrates of semi-insulating Ga2O3 and 4H-SiC. Electron mobility in β-Ga2O3 is negatively affected by increasing lattice temperature, which consequently also negatively influences device conductance. The superior thermal conductivity of 4H-SiC substrates resulted in reduced ß-Ga2O3 lattice temperatures and, thus, mitigates MESFET drain current degradation. This, in turn, allows practically reduced device dimensions without deteriorating the performance and improved device reliability.
The performance of devices has been improved with fine processes from planar to three-dimensional transistors (e.g., FinFET, NWFET, and MBCFET). There are some problems such as a short channel effect or a self-heating effect occur due to the reduction of the gate-channel length by miniaturization. To solve these problems, we compare and analyze the electrical and thermal characteristics of FinFET and GAAFET devices that are currently used and expected to be further developed in the future. In addition, the optimal structure according to the Fin shape was investigated. GAAFET is a suitable device for use in a smaller scale process than the currently used, because it shows superior electrical and thermal resistance characteristics compared to FinFET. Since there are pros and cons in process difficulty and device characteristics depending on the channel formation structure of GAAFET, we expect a mass-production of fine processes over 5 nm through structural optimization is feasible.