摘要
A new SOl self-balance (SB) super-junction (S J) pLDMOS with a self-adaptive charge (SAC) layer and its physical model are presented. The SB is an effective way to realize charges balance (CB). The substrate-assisted depletion (SAD) effect of the lateral SJ is eliminated by the self-adaptive inversion electrons provided by the SAC. At the same time, high concentration dynamic self-adaptive electrons effectively enhance the electric field (EI) of the dielectric buried layer and increase breakdown voltage (BV). E1 = 600 V/μm and BV =- 237 V are obtained by 3D simulation on a 0.375-μm-thick dielectric layer and a 2.5-μm-thick top silicon layer. The optimized structure realizes the specific on resistance (Ron,sp) of 0.01319Ω·cm2, FOM (FOM = BV2/R p) of 4.26 MW/cm2 under a 11 μm length (Ld) drift region.
A new SOl self-balance (SB) super-junction (S J) pLDMOS with a self-adaptive charge (SAC) layer and its physical model are presented. The SB is an effective way to realize charges balance (CB). The substrate-assisted depletion (SAD) effect of the lateral SJ is eliminated by the self-adaptive inversion electrons provided by the SAC. At the same time, high concentration dynamic self-adaptive electrons effectively enhance the electric field (EI) of the dielectric buried layer and increase breakdown voltage (BV). E1 = 600 V/μm and BV =- 237 V are obtained by 3D simulation on a 0.375-μm-thick dielectric layer and a 2.5-μm-thick top silicon layer. The optimized structure realizes the specific on resistance (Ron,sp) of 0.01319Ω·cm2, FOM (FOM = BV2/R p) of 4.26 MW/cm2 under a 11 μm length (Ld) drift region.
基金
Project supported by the National Natural Science Foundation of China(No.61306094)
the Project of Sichuan Provincial Education Department(No.13ZA0089)
the Research Fund for the Middle and Youth Academic Leader of Chengdu University of Information Technology(No.J201301)
