漏致势垒降低效应对短沟道应变硅金属氧化物半导体场效应管阈值电压的影响

结合应变硅金属氧化物半导体场效应管(MOSFET)结构,通过求解二维泊松方程,得到了应变Si沟道的电势分布,并据此建立了短沟道应变硅NMOSFET的阈值电压模型.依据计算结果,详细分析了弛豫Si_1－βGe_β中锗组分β、沟道长度、漏电压、衬底掺杂浓度以及沟道掺杂浓度对阈值电压的影响,从而得到漏致势垒降低效应对小尺寸应变硅器件阈值电压的影响,对应变硅器件以及电路的设计具有重要的参考价值. 关键词： 应变硅金属氧化物半导体场效应管 漏致势垒降低 二维泊松方程 阈值电压模型     

单Halo全耗尽应变Si 绝缘硅金属氧化物半导体场效应管的阈值电压解析模型

为了改善金属氧化物半导体场效应管(MOSFET) 的短沟道效应(SCE)、 漏致势垒降低(DIBL) 效应, 提高电流的驱动能力, 提出了单Halo 全耗尽应变硅绝缘体 (SOI) MOSFET 结构, 该结构结合了应变Si, 峰值掺杂Halo结构, SOI 三者的优点. 通过求解二维泊松方程, 建立了全耗尽器件表面势和阈值电压的解析模型. 模型中分析了弛豫层中的Ge组分对表面势、表面场强和阈值电压的影响, 不同漏电压对表面势的影响, Halo 掺杂对阈值电压和DIBL的影响.结果表明, 该新结构能够抑制SCE和DIBL效应, 提高载流子的输运效率. 关键词： 应变Si 阈值电压 短沟道效应 漏致势垒降低     

高k栅介质GeOI金属氧化物半导体场效应管阈值电压和亚阈斜率模型及其器件结构设计

通过求解沟道与埋氧层的二维泊松方程,同时考虑垂直沟道与埋氧层方向的二阶效应,建立了高κ栅介质GeOI金属氧化物半导体场效应管(MOSFET)的阈值电压和亚阈斜率解析模型,研究了器件主要结构参数对器件阈值特性、亚阈特性、短沟道效应、漏极感应势垒降低效应及衬偏效应的影响,提出了优化器件性能的结构参数设计原则及取值范围,模拟结果与TCAD仿真结果符合较好,证实了模型的正确性与实用性。     

堆叠栅介质对称双栅单Halo应变Si金属氧化物半导体场效应管二维模型

提出了一种堆叠栅介质对称双栅单Halo应变Si金属氧化物半导体场效应管(metal-oxide semiconductor field effect transistor,MOSFET)新器件结构.采用分区的抛物线电势近似法和通用边界条件求解二维泊松方程,建立了全耗尽条件下的表面势和阈值电压的解析模型.该结构的应变硅沟道有两个掺杂区域,和常规双栅器件(均匀掺杂沟道)比较,沟道表面势呈阶梯电势分布,能进一步提高载流子迁移率;探讨了漏源电压对短沟道效应的影响;分析得到阈值电压随缓冲层Ge组分的提高而降低,随堆叠栅介质高k层介电常数的增大而增大,随源端应变硅沟道掺杂浓度的升高而增大,并解释了其物理机理.分析结果表明:该新结构器件能够更好地减小阈值电压漂移,抑制短沟道效应,为纳米领域MOSFET器件设计提供了指导.     

高k栅介质应变Si SOI MOSFET的阈值电压解析模型

在结合应变Si,高k栅和SOI结构三者的优点的基础上,提出了一种新型的高k栅介质应变Si全耗尽SOI MOSFET结构.通过求解二维泊松方程建立了该新结构的二维阈值电压模型,在该模型中考虑了影响阈值电压的主要参数.分析了阈值电压与弛豫层中的Ge组分、应变Si层厚度的关系.研究结果表明阈值电压随弛豫层中Ge组分的提高和应变Si层的厚度增加而降低.此外,还分析了阈值电压与高k栅介质的介电常数和应变Si层的掺杂浓度的关系.研究结果表明阈值电压随高k介质的介 关键词： 应变Si k栅')" href="#">高k栅 短沟道效应 漏致势垒降低     

SiC肖特基源漏MOSFET的阈值电压

SiC肖特基源漏MOSFET的阈值电压不同于传统的MOSFET的阈值电压.在深入分析工作机理的基础上,利用二维模拟软件ISE提取并分析了器件的阈值电压.对SiC肖特基源漏MOSFET的阈值电压给出物理描述,得出当源极载流子主要以场发射方式进入沟道,同时沟道进入强反型状态,此时的栅电压是该器件的阈值电压. 关键词： 碳化硅 肖特基接触 阈值电压     

应变Si NMOSFET阈值电压集约物理模型

本文采用渐变沟道近似和准二维分析的方法, 通过求解泊松方程, 建立了应变Si NMOSFET阈值电压集约物理模型. 模型同时研究了短沟道, 窄沟道, 非均匀掺杂, 漏致势垒降低等物理效应对阈值电压的影响. 采用参数提取软件提取了阈值电压相关参数, 通过将模型的计算结果和实验结果进行对比分析, 验证了本文提出的模型的正确性. 该模型为应变Si超大规模集成电路的分析和设计提供了重要的参考. 关键词： 应变Si NMOSFET 阈值电压 集约物理模型     

一个圆柱形双栅场效应晶体管的物理模型

圆柱形双栅场效应晶体管(CSDG MOSFET)是在围栅MOSFET器件增加内部控制栅而形成,与双栅、三栅及围栅MOSFET器件相比,圆柱形双栅MOSFET提供了更好的栅控性能和输出特性.本文通过求解圆柱坐标系下的二维泊松方程,得到了圆柱形双栅MOSFET的电势模型;进一步对反型电荷沿沟道积分,建立其漏源电流模型.分析讨论了圆柱形双栅MOSFET器件的电学特性,结果表明:圆柱形双栅MOSFET外栅沿沟道的最小表面势和器件的阈值电压随栅介质层介电常数的增大而减小,其漏源电流和跨导随栅介质层介电常数的增大而增大;随着器件参数的等比例缩小,沟道反型电荷密度减小,其漏源电流和跨导也减小.     

量子阱Si/SiGe/Sip型场效应管阈值电压和沟道空穴面密度模型

Si材料中较低的空穴迁移率限制了Si互补金属氧化物半导体器 件在高频领域的应用. 针对SiGe p型金属氧化物半导体场效应管(PMOSFET)结构, 通过求解纵向一维泊松方程,得到了器件的纵向电势分布, 并在此基础上建立了器件的阈值电压模型,讨论了Ge组分、缓冲层厚度、 Si帽层厚度和衬底掺杂对阈值电压的影响.由于SiGe沟道层较薄, 计算中考虑了该层价带势阱中的量子化效应. 当栅电压绝对值过大时, 由于能带弯曲和能级分裂造成SiGe沟道层中的空穴会越过势垒到达Si/SiO₂界面, 从而引起器件性能的退化. 建立了量子阱SiGe PMOSFET沟道层的空穴面密度模型, 提出了最大工作栅电压的概念, 对由栅电压引起的沟道饱和进行了计算和分析. 研究结果表明,器件的阈值电压和最大工作栅压与SiGe层Ge组分关系密切, Ge组分的适当提高可以使器件工作栅电压范围有效增大.     

对称三材料双栅应变硅金属氧化物半导体场效应晶体管二维解析模型

提出了对称三材料双栅应变硅金属氧化物半导体场效应晶体管器件结构,为该器件结构建立了全耗尽条件下的表面势模型、表面场强和阈值电压解析模型,并分析了应变对表面势、表面场强和阈值电压的影响,讨论了三栅长度比率对阈值电压和漏致势垒降低效应的影响,对该结构器件与单材料双栅结构器件的性能进行了对比研究.结果表明,该结构能进一步提高载流子的输运速率,更好地抑制漏致势垒降低效应.适当优化三材料栅的栅长比率,可以增强器件对短沟道效应和漏致势垒降低效应的抑制能力.     

Two-dimensional analytical models for asymmetric fully depleted double-gate strained silicon MOSFETs

This paper develops the simple and accurate two-dimensional analytical models for new asymmetric double-gate fully depleted strained-Si MOSFET. The models mainly include the analytical equations of the surface potential, surface electric field and threshold voltage, which are derived by solving two dimensional Poisson equation in strained-Si layer. The models are verified by numerical simulation. Besides offering the physical insight into device physics in the model, the new structure also provides the basic designing guidance for further immunity of short channel effect and drain-induced barrier-lowering of CMOS-based devices in nanometre scale.     

A threshold voltage model of short-channel fully-depleted recessed-source/drain(Re-S/D) SOI MOSFETs with high-k dielectric

In this paper, a surface potential based threshold voltage model of fully-depleted(FD) recessed-source/drain(Re-S/D)silicon-on-insulator(SOI) metal-oxide semiconductor field-effect transistor(MOSFET) is presented while considering the effects of high-k gate-dielectric material induced fringing-field. The two-dimensional(2D) Poisson's equation is solved in a channel region in order to obtain the surface potential under the assumption of the parabolic potential profile in the transverse direction of the channel with appropriate boundary conditions. The accuracy of the model is verified by comparing the model's results with the 2D simulation results from ATLAS over a wide range of channel lengths and other parameters,including the dielectric constant of gate-dielectric material.     

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.     

高功率微波作用下金属氧化物半导体场效应管响应

采用基于半导体漂移扩散模型的数值模拟软件对高功率微波(HPM)作用下金属氧化物半导体场效应管(MOSFET)的响应进行了数值模拟研究。对MOSFET在HPM作用下的输出特性以及器件内部响应进行了数值模拟。计算结果表明,在MOSFET栅极加载HPM后,随着注入HPM幅值的增大,会使得器件的正向电压小于开启电压,从而使得输出电流的波形发生形变。在器件内部,导电沟道靠近源极一端的电场强度最大,热量产生集中在这一区域。在脉冲正半周期时,温度峰值位于沟道源极一端,负半周期时,器件内部几乎没有电流,器件内的温度峰值在热扩散效应的影响下趋向于导电沟道中部。     

Quasi-two-dimensional threshold voltage model for junctionless cylindrical surrounding gate metal-oxide-semiconductor field-effect transistor with dual-material gate

Based on the quasi-two-dimensional(2D) solution of Poisson’s equation in two continuous channel regions, an analytical threshold voltage model for short-channel junctionless dual-material cylindrical surrounding-gate(JLDMCSG) metal-oxide-semiconductor field-effect transistor(MOSFET) is developed. Using the derived model, channel potential distribution, horizontal electrical field distribution, and threshold voltage roll-off of JLDMCSG MOSFET are investigated. Compared with junctionless single-material CSG(JLSGCSG) MOSFET, JLDMCSG MOSFET can effectively suppress short-channel effects and simultaneously improve carrier transport efficiency. It is also revealed that threshold voltage rolloff of JLDMCSG can be significantly reduced by adopting both a small oxide thickness and a small silicon channel radius. The model is verified by comparing its calculated results with that obtained from three-dimensional(3D) numerical device simulator ISE.     

Analytical model including the fringing-induced barrier lowering effect for a dual-material surrounding-gate MOSFET with a high-kappa gate dielectric

By solving Poisson's equation in both semiconductor and gate insulator regions in the cylindrical coordinates, an analytical model for a dual-material surrounding-gate (DMSG) metal-oxide semiconductor field-effect transistor (MOSFET) with a high-kappa gate dielectric has been developed. Using the derived model, the influences of fringing-induced barrier lowering (FIBL) on surface potential, subthreshold current, DIBL, and subthreshold swing are investigated. It is found that for the same equivalent oxide thickness, the gate insulator with high-kappa dielectric degrades the short-channel performance of the DMSG MOSFET. The accuracy of the analytical model is verified by the good agreement of its results with that obtained from the ISE three-dimensional numerical device simulator.     

A threshold voltage analytical model for high-k gate dielectric MOSFETs with fully overlapped lightly doped drain structures

We investigate the influence of voltage drop across the lightly doped drain(LDD) region and the built-in potential on MOSFETs,and develop a threshold voltage model for high-k gate dielectric MOSFETs with fully overlapped LDD structures by solving the two-dimensional Poisson’s equation in the silicon and gate dielectric layers.The model can predict the fringing-induced barrier lowering effect and the short channel effect.It is also valid for non-LDD MOSFETs.Based on this model,the relationship between threshold voltage roll-off and three parameters,channel length,drain voltage and gate dielectric permittivity,is investigated.Compared with the non-LDD MOSFET,the LDD MOSFET depends slightly on channel length,drain voltage,and gate dielectric permittivity.The model is verified at the end of the paper.