Superjunction Power Transistors With Interface Charges: A Case Study for GaN

• Main Authors: Yunwei Ma, Ming Xiao, Ruizhe Zhang, Han Wang, Yuhao Zhang
• Format: Article
• Language: English
• Published: IEEE 2020-01-01
• Series: IEEE Journal of the Electron Devices Society
• Subjects: Power electronics; power semiconductor devices; superjunction; interface charges; interface impurities; gallium nitride
• Online Access: https://ieeexplore.ieee.org/document/8932530/

Recent progress in p-GaN trench-filling epitaxy has shown promise for the demonstration of GaN superjunction (SJ) devices. However, the presence of n-type interface charges at the regrowth interfaces has been widely observed. These interface charges pose great challenges to the design and performance evaluation of SJ devices. This work presents an analytical model for SJ devices with interface charges for the first time. In our model, two approaches are proposed to compensate interface charges, by the modulation of the SJ doping or the SJ geometry. Based on our model, an analytical study is conducted for GaN SJ transistors, revealing the design windows and optimal values of doping concentration and pillar width as a function of interface charge density. Finally, TCAD simulation is performed for vertical GaN SJ transistors, which validated our analytical model. Our results show that, with optimal designs, interface charges would only induce small degradation in the performance of GaN SJ devices. However, with the increased interface charge density, the design windows for pillar width and doping concentration become increasingly narrow and the upper limit in the pillar width window reduces quickly. When the interface charge density exceeds $\sim 3\times 10^{12}$ cm^-2, the design window of pillar width completely falls into the sub-micron range, indicating significant difficulties in fabrication. Vertical GaN SJ transistors with interface charges retain great advantages over conventional GaN power transistors, but have narrower design windows and require different design rules compared to ideal GaN SJ devices.