Abstract
We propose a novel silicon carbide (SiC) self-aligned N-type ion implanted trench MOSFET (NITMOS) device. The maximum electric field in the gate oxide could be effectively reduced to below 3 MV/cm with the introduction of the P-epi layer below the trench. The P-epi layer is partially counter-doped by a self-aligned N-type ion implantation process, resulting in a relatively low specific on-resistance (R(on,sp)). The lateral spacing between the trench sidewall and N-implanted region (W(sp)) plays a crucial role in determining the performance of the SiC NITMOS device, which is comprehensively studied through the numerical simulation. With the W(sp) increasing, the SiC NITMOS device demonstrates a better short-circuit capability owing to the reduced saturation current. The gate-to-drain capacitance (C(gd)) and gate-to-drain charge (Q(gd)) are also investigated. It is observed that both C(gd) and Q(gd) decrease as the W(sp) increases, owing to the enhanced screen effect. Compared to the SiC double-trench MOSFET device, the optimal SiC NITMOS device exhibits a 79% reduction in C(gd), a 38% decrease in Q(gd), and a 41% reduction in Q(gd) × R(on,sp). A higher switching speed and a lower switching loss can be achieved using the proposed structure.