一种非对称双栅应变硅HALO掺杂沟道MOSFET阈值电压解析模型

提出了一种非对称双栅应变硅HALO掺杂沟道金属氧化物半导体场效应管结构.该器件前栅和背栅由两种不同功函数的金属构成,沟道为应变硅HALO掺杂沟道,靠近源区为低掺杂区域,靠近漏区为高掺杂区域.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,分别求解了前背栅表面势、前背栅表面电场及前背栅阈值电压,建立了双栅器件的表面势、表面电场和阈值电压解析模型.详细讨论了物理参数对解析模型的影响.研究结果表明,该器件能够很好的抑制短沟道效应、热载流子效应和漏致势垒降低效应.模型解析结果与DESSIS仿真结果吻合较好,证明了该模型的正确性.     

异质栅全耗尽型应变硅 SOI MOSFET二维解析模型*

本文首次并建立了异质栅全耗尽型应变Si SOI (DMG SSOI) MOSFET的二维表面势沿沟道变化的模型．并对该结构的MOSFET的短沟道效应SCE (short channel effect),热载流子效应HCE(hot carrier effect),漏致势垒降低DIBL (drain induced barrier lowering)和载流子传输效率进行了研究．该模型中考虑以下参数：金属栅长,金属栅的功函数,漏电压和Ge在驰豫SiGe中的摩尔组分．结果表明沟道区的表面势引进了阶梯分布,正是这个阶梯分布的表面势抑制了SCE,HCE和DIBL．同时,应变硅和SOI(silicon-on-insulator)结构都能提高载流子的传输效率,特别是应变硅能提高载流子的传输效率．此外阈值电压模型能者正确表明阈值电压随栅长比率L2/L1减小或应变Si膜中Ge摩尔组分的降低而升高．数值模拟器ISE验证了该模型的正确性．     

一种新型全耗尽双栅MOSFET

提出一种新型全耗尽双栅MOSFET,该器件具有异质栅和LDD结构.异质栅由主栅和两个侧栅组成,分区控制器件的沟道表面势垒.通过Tsuprem-4工艺模拟和Medici器件模拟验证表明,与普通双栅全耗尽SOI相比,该器件获得了更好的开态/关态电流比和亚阈值斜率.在0.18μm工艺下,开态/关态电流比约为1010,亚阈值斜率接近60mV/dec.     

一种新型全耗尽双栅MOSFET

提出一种新型全耗尽双栅MOSFET,该器件具有异质栅和LDD结构.异质栅由主栅和两个侧栅组成,分区控制器件的沟道表面势垒.通过Tsuprem-4工艺模拟和Medici器件模拟验证表明,与普通双栅全耗尽SOI相比,该器件获得了更好的开态/关态电流比和亚阈值斜率.在0.18μm工艺下,开态/关态电流比约为1010,亚阈值斜率接近60mV/dec.     

全耗尽异质栅单Halo SOI MOSFET二维模型

为了抑制深亚微米SOI MOSFET的短沟道效应,并提高电流驱动能力,提出了异质栅单Halo SOI MOSFET器件结构,其栅极由具有不同功函数的两种材料拼接而成,并在沟道源端一侧引入Halo技术.采用分区的抛物线电势近似法和通用边界条件求解二维Poisson方程,为新结构器件建立了全耗尽条件下的表面势及阈值电压二维解析模型.对新结构器件与常规SOI MOSFET性能进行了对比研究.结果表明,新结构器件能有效抑制阈值电压漂移、热载流子效应和漏致势垒降低效应,并显著提高载流子通过沟道的输运速度.解析模型与器件数值模拟软件MEDICI所得结果高度吻合.     

异质栅非对称Halo SOI MOSFET

为了抑制异质栅SOI MOSFET的漏致势垒降低效应,在沟道源端一侧引入了高掺杂Halo结构.通过求解二维电势Poisson方程,为新结构器件建立了全耗尽条件下表面势和阈值电压解析模型,并对其性能改进情况进行了研究.结果表明,新结构器件比传统的异质栅SOI MOSFETs能更有效地抑制漏致势垒降低效应,并进一步提高载流子输运效率.新结构器件的漏致势垒降低效应随着Halo区掺杂浓度的增加而减弱,但随Halo区长度非单调变化.解析模型与数值模拟软件MEDICI所得结果高度吻合.     

异质栅非对称Halo SOI MOSFET

为了抑制异质栅SOI MOSFET的漏致势垒降低效应，在沟道源端一侧引入了高掺杂Halo结构．通过求解二维电势Poisson方程，为新结构器件建立了全耗尽条件下表面势和阈值电压解析模型，并对其性能改进情况进行了研究．结果表明，新结构器件比传统的异质栅SOI MOSFETs能更有效地抑制漏致势垒降低效应，并进一步提高载流子输运效率．新结构器件的漏致势垒降低效应随着Halo区掺杂浓度的增加而减弱，但随Halo区长度非单调变化．解析模型与数值模拟软件MEDICI所得结果高度吻合．     

短沟道双栅MOSFET二维表面势解析模型

采用分解电势的方法求解二维泊松方程,建立了考虑电子准费米势的短沟道双栅MOSFET的二维表面势模型,并在其基础上导出了阈值电压、短沟道致阈值电压下降效应和漏极感应势垒降低效应的解析模型。研究了不同沟道长度、栅压和漏压情况下的沟道表面势,分析了沟道长度和硅膜厚度对短沟道效应的影响。研究结果表明,电子准费米势对开启后的器件漏端附近表面势有显著影响,新模型可弥补现有模型中漏端附近表面势误差较大的缺点;对于短沟道双栅MOSFET,适当减小硅膜厚度可抑制短沟道效应。     

隐埋层中二维效应对全耗尽SOI非对称HALO结构阈值电压的影响

在非对称HALO结构的全耗尽SOI二维阈值电压解析模型的基础上,对阈值电压受隐埋层中二维效应的影响进行了讨论.通过与一维模型的比较,说明在深亚微米SOI MOSFET器件中隐埋层的二维效应会导致器件提前出现短沟道效应.新模型结果与二维数值模拟软件MEDICI吻合较好.     

隐埋层中二维效应对全耗尽SOI非对称HALO结构阈值电压的影响

在非对称HALO结构的全耗尽SOI二维阈值电压解析模型的基础上,对阈值电压受隐埋层中二维效应的影响进行了讨论.通过与一维模型的比较,说明在深亚微米SOI MOSFET器件中隐埋层的二维效应会导致器件提前出现短沟道效应.新模型结果与二维数值模拟软件MEDICI吻合较好.     

A two-dimensional analytical model of fully depleted asymmetrical dual material gate double-gate strained-Si MOSFETs

On the basis of the exact resultant solution of two dimensional Poisson’s equations,a new accurate two-dimensional analytical model comprising surface channel potentials,a surface channel electric field and a threshold voltage for fully depleted asymmetrical dual material gate double-gate strained-Si MOSFETs is successfully developed. The model shows its validity by good agreement with the simulated results from a two-dimensional numerical simulator.Besides offering a physical insight into device physics,the model provides basic design guidance for fully depleted asymmetrical dual material gate double-gate strained-Si MOSFETs.     

Two-dimensional threshold voltage analytical modes of DMG strained-silicon-on-insulator MOSFETs

For the first time, a simple and accurate two-dimensional analytical model for the surface potential variation along the channel in fully depleted dual-material gate strained-Si-on-insulator (DMG SSOI) MOSFETs is developed. We investigate the improved short channel effect (SCE), hot carrier effect (HCE), drain-induced barrier-lowering (DIBL) and carrier transport efficiency for the novel structure MOSFET. The analytical model takes into account the effects of different metal gate lengths, work functions, the drain bias and Ge mole fraction in the relaxed SiGe buffer. The surface potential in the channel region exhibits a step potential, which can suppress SCE, HCE and DIBL. Also, strained-Si and SOI structure can improve the carrier transport efficiency, with strained-Si being particularly effective. Further,the threshold voltage model correctly predicts a "rollup" in threshold voltage with decreasing channel length ratios or Ge mole fraction in the relaxed SiGe buffer. The validity of the two-dimensional analytical model is verified using numerical simulations.     

A physical compact DC drain current model for long-channel undoped ultra-thin body (UTB) SOI and asymmetric double-gate (DG) MOSFETs with independent gate operation

In this paper, a new compact charge based DC model for the drain current of long channel fully depleted ultra-thin body SOI MOSFETs and asymmetric double-gate MOSFETs with independent gate operation (ADGMOSFETs) is presented. The model was validated by both TCAD simulations and electrical measurements with a good agreement. In particular, great care was taken during the derivation of the model in order to respect the physics of the device and to make the correct approximations. The obtained solutions can be viewed as a generalization of classical MOS theory to the case of undoped fully depleted ADGMOS. As a result, the model consists of relatively simple equations and is a promising approach for the compact modeling and parameter extraction of fully depleted SOI transistors.     

垂直双栅双应变沟道的MOSFETs特性分析

A novel device structure with a vertical double-gate and dual-strained channel is presented.The electrical characteristics of this device with a gate length of 100 nm are simulated.With a Ge content of 20%,the drain currents of the strained-Si NMOSFET and the strained-SiGe PMOSFET compared to the universal SOI MOSFETs are enhanced by 26% and 33%,respectively;the risetime and the falltime of the strained-channel CMOS are greatly decreased by 50% and 25.47% compared to their traditional Si channel counterparts.The simulation results show that the vertical double-gate（DG） dual-strained-channel MOSFETs exhibit better drive capability,a higher transconductance,and a faster circuit speed for CMOS compared to conventional-Si MOSFETs.The new structure can be achieved by today＇s semiconductor manufacturing level.     

Characteristics of vertical double-gate dual-strained-channel MOSFET

A novel device structure with a vertical double-gate and dual-strained channel is presented. The electrical characteristics of this device with a gate length of 100 nm are simulated. With a Ge content of 20%, the drain currents of the strained-Si NMOSFET and the strained-SiGe PMOSFET compared to the universal SOI MOSFETs are enhanced by 26% and 33%, respectively; the risetime and the falltime of the strained-channel CMOS are greatly decreased by 50% and 25.47% compared to their traditional Si channel counterparts. The simulation results show that the vertical double-gate (DG) dual-strained-channel MOSFETs exhibit better drive capability, a higher transconductance, and a faster circuit speed for CMOS compared to conventional-Si MOSFETs. The new structure can be achieved by today's semiconductor manufacturing level.     

Comparative analysis of the DC performance of DG MOSFETs on highly-doped and near-intrinsic silicon layers

A comparison of dc characteristics of fully depleted double-gate (DG) MOSFETs with respect to low-power circuit applications and device scaling has been performed by two-dimensional device simulation. Three different DG MOSFET structures including a conventional N⁺ polysilicon gate device with highly doped Si layer, an asymmetrical P⁺/N⁺ polysilicon gate device with low doped Si layer and a mid-gap metal gate device with low doped Si layer have been analysed. It was found that DG MOSFET with mid-gap metal gates yields the best dc parameters for given off-state drain leakage current and highest immunity to the variation of technology parameters (gate length, gate oxide thickness and Si layer thickness). It is also found that an asymmetrical P⁺/N⁺ polysilicon gate DG MOSFET design offers comparable dc characteristics, but better parameter immunity to technology tolerances than a conventional DG MOSFET.     

Two-dimensional threshold voltage analytical model of DMG strained-silicon-on-insulator MOSFETs

For the first time,a simple and accurate two-dimensional analytical model for the surface potential variation along the channel in fully depleted dual-material gate strained-Si-on-insulator(DMG SSOI) MOSFETs is developed.We investigate the improved short channel effect(SCE),hot carrier effect(HCE),drain-induced barrier-lowering(DIBL) and carrier transport efficiency for the novel structure MOSFET.The analytical model takes into account the effects of different metal gate lengths,work functions,the drain ...     

Analytical modeling of drain current and RF performance for double-gate fully depleted nanoscale SOI MOSFETs

A new 2D analytical drain current model is presented for symmetric double-gate fully depleted nanoscale SOI MOSFETs. Investigation of device parameters like transconductance for double-gate fully depleted nanoscale SOI MOSFETs is also carried out. Finally this work is concluded by modeling the cut-off frequency, which is one of the main figures of merit for analog/RF performance for double-gate fully depleted nanoscale SOI MOSFETs. The results of the modeling are compared with those obtained by a 2D ATLAS device simulator to verify the accuracy of the proposed model.     

全耗尽SOI MOSFETs阈值电压解析模型

提出了一种新的全耗尽SOI MOSFETs阈值电压二维解析模型.通过求解二维泊松方程得到器件有源层的二维电势分布函数,氧化层-硅界面处的电势最小值用于监测SOI MOSFETs的阈值电压.通过对不同栅长、栅氧厚度、硅膜厚度和沟道掺杂浓度的SOI MOSFETs的MEDICI模拟结果的比较,验证了该模型,并取得了很好的一致性.