n型金属氧化物半导体场效应晶体管噪声非高斯性研究

基于n型金属氧化物半导体场效应晶体管（nMOSFET）噪声的数涨落模型,采用高阶统计量双相干系数平方和研究了nMOSFET噪声的非高斯性.通过对nMOSFET实际测试噪声的分析,发现nMOSFET器件噪声存在非高斯性;小尺寸器件噪声的非高斯性强于大尺寸器件;在器件的强反型线性区,其非高斯性随着漏压的增加而增加.文中还通过蒙特卡罗模拟和中心极限定理理论对nMOSFET噪声的非高斯性作了深入的探讨. 关键词： 噪声 非高斯性 n型金属氧化物半导体场效应晶体管 氧化层陷阱     

阶梯氧化层新型折叠硅横向双扩散功率器件

为了设计功率集成电路所需的低功耗横向功率器件, 提出了一种具有阶梯氧化层折叠硅横向双扩散金属-氧化物-半导体(step oxide folding LDMOS, SOFLDMOS)新结构. 这种结构将阶梯氧化层覆盖在具有周期分布的折叠硅表面, 利用阶梯氧化层的电场调制效应, 通过在表面电场分布中引入新的电场峰而使表面电场分布均匀, 提高了器件的耐压范围, 解决了文献提出的折叠积累型横向双扩散金属-氧化物-半导体器件击穿电压受限的问题. 通过三维仿真软件ISE分析获得, SOFLDMOS 结构打破了硅的极限关系, 充分利用了电场调制效应、多数载流子积累和硅表面导电区倍增效应, 漏极饱和电流比一般LDMOS 提高3.4倍左右, 可以在62 V左右的反向击穿电压条件下, 获得0.74 mΩ·cm²超低的比导通电阻, 远低于传统LDMOS相同击穿电压下2.0 mΩ·cm²比导通电阻, 为实现低压功率集成电路对低功耗横向功率器件的要求提供了一种可选的方案.     

Modeling of the drain-induced barrier lowering effect and optimization for a dual-channel 4H silicon carbide metal semiconductor field effect transistor

A new analytical model to describe the drain-induced barrier lowering (DIBL) effect has been obtained by solving the two-dimensional (2D) Poisson's equation for the dual-channel 4H-SiC MESFET (DCFET). Using this analytical model, we calculate the threshold voltage shift and the sub-threshold slope factor of the DCFET, which characterize the DIBL effect. The results show that they are significantly dependent on the drain bias, gate length as well as the thickness and doping concentration of the two channel layers. Based on this analytical model, the structure parameters of the DCFET have been optimized in order to suppress the DIBL effect and improve the performance.     

Model and analysis of drain induced barrier lowering effect for 4H--SiC metal semiconductor field effect transistor

Based on an analytical solution of the two-dimensional Poisson equation in the subthreshold region, this paper investigates the behavior of DIBL (drain induced barrier lowering) effect for short channel 4H--SiC metal semiconductor field effect transistors (MESFETs). An accurate analytical model of threshold voltage shift for the asymmetric short channel 4H--SiC MESFET is presented and thus verified. According to the presented model, it analyses the threshold voltage for short channel device on the L/a (channel length/channel depth) ratio, drain applied voltage V_DS and channel doping concentration N_D, thus providing a good basis for the design and modelling of short channel 4H--SiC MESFETs device.     

Modeling of the drain-induced barrier lowering effect and optimization for a dual-channel 4H silicon carbide metal semiconductor field effect transistor

A new analytical model to describe the drain-induced barrier lowering(DIBL) effect has been obtained by solving the two-dimensional(2D) Poisson’s equation for the dual-channel 4H-SiC MESFET(DCFET).Using this analytical model,we calculate the threshold voltage shift and the sub-threshold slope factor of the DCFET,which characterize the DIBL effect.The results show that they are significantly dependent on the drain bias,gate length as well as the thickness and doping concentration of the two channel layers.Based on this analytical model,the structure parameters of the DCFET have been optimized in order to suppress the DIBL effect and improve the performance.     

A novel partial SOI LDMOSFET with a trench and buried P layer for breakdown voltage improvement

In this paper for the first time, a partial silicon-on-insulator (PSOI) lateral double-diffused metal-oxide-semiconductor-field-effect-transistor (LDMOSFET) is proposed with a novel trench which improves breakdown voltage. The introduced trench in the partial buried oxide enhances peak of the electric field and is positioned in the drain side of the drift region to maximize breakdown voltage. We demonstrate that the electric field is modified by producing two additional electric field peaks, which decrease the common peaks near the drain and gate junctions in the trench-partial-silicon-on-insulator (T-PSOI) structure. Hence, a more uniform electric field is obtained. Two dimensional (2D) simulations show that the breakdown voltage of T-PSOI is nearly 64% higher in comparison with partial silicon on insulator (PSOI) structure and alleviate self heating effect approximately 9% and 15% in comparison with its conventional PSOI (C-PSOI) and conventional SOI (C-SOI) counterparts respectively. In addition the current of the T-PSOI, C-PSOI, conventional SOI (C-SOI), and fully depleted conventional SOI (FC-SOI) structures are 90, 82, 74, and 44 μA, respectively for a drain–source voltage V_DS = 30 V and gate–source voltage V_GS = 10 V.