Improved specific on-resistance (Ron,sp) in beta-gallium oxide (β-Ga2O3) trench Schottky barrier diodes (TSBDs) is achieved without the usual trade-off of reduced breakdown voltage, enabled through the use of a double drift layer (DDL) TSBD architecture; this incorporates a Si-doped drift layer atop an unintentionally doped (UID) drift region. DDL TSBDs show a 46% reduction in Ron,sp compared to single-UID drift layer TSBDs, while maintaining a similar Vbr of 2.6–2.7 kV. As a result, the DDL TSBD design enhances Baliga's figure-of-merit from 481 MW/cm2 for conventional TSBDs to 959 MW/cm2, marking a twofold improvement. Silvaco TCAD simulations further confirm that both structures exhibit similar dominant peak electric fields at the trench corners, consistent with their comparable breakdown voltages. While reducing fin width in TSBDs enhances Vbr because of an improved reduced surface field effect, we demonstrate that this effect is significantly amplified in DDL TSBDs, enabling a substantial shift in the conventional Ron,sp–Vbr trajectory.
Vanjari et al. (Mon,) studied this question.