Abstract
A split-gate metal–oxide–semiconductor field-effect transistor (SG-DMOSFET) is a well-known structure used for reducing the gate–drain capacitance (CGD) to improve switching characteristics. However, SG-DMOSFETs have problems such as the degradation of static characteristics and a high gate-oxide electric field. To solve these problems, we developed a SG-DMOSFET with floating p+ polysilicon (FPS-DMOSFET) and compared it with a conventional planar DMOSFET (C-DMOSFET) and a SG-DMOSFET through Technology Computer-Aided Design (TCAD) simulations. In the FPS-DMOSFET, floating p+ polysilicon (FPS) is inserted between the active gates to disperse the high drain voltage in the off state and form an accumulation layer over the entire junction field effect transistor (JFET) region, similar to a C-DMOSFET, in the on state. Therefore, the FPS-DMOSFET can minimize the degradation of static characteristics such as the breakdown voltage (BV) and specific on resistance (RON,SP) in the split-gate structure. Consequently, the FPS-DMOSFET can shorten the active gate length and achieve a gate-to-drain capacitance (CGD) that is less than those of the C-DMOSFET and SG-DMOSFET by 48% and 41%, respectively. Moreover, the high-frequency figure of merit (HF-FOM = RON,SP × CGD) of the FPS-DMOSFET is lower than those of the C-DMOSFET and SG-DMOSFET by 61% and 49%, respectively. In addition, the FPS-DMOSFET shows an EMOX of 2.1 MV/cm, which guarantees a gate oxide reliability limit of 3 MV/cm. Therefore, the proposed FPS-DMOSFET is the most appropriate device to be used in high-voltage and high-frequency electronic applications.
Highlights
Accepted: 8 March 20214H-SiC metal-oxide-semiconductor field-effect transistors (MOSFETs) are considered promising candidates for high-temperature and high-voltage applications [1,2]
A decrease in LSG leads to a decrease in CGD, which improves the highfrequency figure of merit (HF-FOM); it causes deterioration of static characteristics such as breakdown voltage (BV) and RON,SP
LSG should be optimized to enhance the performance of the proposed floating p+ polysilicon (FPS)-DMOSFET, considering both Baliga’s figure of merit (BFOM) and HF-FOM
Summary
4H-SiC metal-oxide-semiconductor field-effect transistors (MOSFETs) are considered promising candidates for high-temperature and high-voltage applications [1,2]. This structure improves HF-FOM through reduction of CGD by decreasing the active gate. Length protruding into the n-drift region (LSG ) This structure substantially decreases Baliga’s figure of merit (BFOM), which is calculated as BV2 /RON,SP [10]. The decrease in BFOM and gate-oxide reliability issues limits the ability of SG-DMOSFETs to improve HF-FOM at high voltages. The FPS-DMOSFET can have a shorter LSG with significantly less BFOM degradation than the SG-DMOSFET It can overcome the problem of electric-field crowding at the active gate oxide, enabling stable operation. The simulation results show that the FPS-DMOSFET achieves the best HF-FOM among the studied structures and an EMOX lower than
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
