n型纳米非对称DG-TFET阈值电压特性研究

n型纳米非对称双栅隧穿场效应晶体管(DG-TFET)速度快、功耗低,在高速低功耗领域具有很好的应用前景,但其阈值电压的表征及其模型与常规MOSFET不同.在深入研究n型纳米非对称DG-TFET的阈值特性基础上,通过求解器件不同区域电场、电势的方法,建立了n型纳米非对称DG-TFET器件阈值电压数值模型,探讨了器件材料物理参数以及漏源电压对阈值电压的影响,通过与Silvaco Atlas的仿真结果比较,验证了模型的正确性.研究表明,n型纳米非对称DG-TFET的阈值电压分别随着栅介质层介电常数的增加、硅层厚度的减薄以及源漏电压的减小而减小,而栅长对其阈值电压的影响有限.该研究对纳米非对称DG-TFET的设计、仿真及制造有一定的参考价值.     

全耗尽SOI MOSFETs阈值电压和电势分布的温度模型

提出了一个全耗尽SOI MOSFETs器件阈值电压和电势分布的温度模型.基于近似的抛物线电势分布模型,利用适当的边界条件对二维的泊松方程进行求解.同时利用阈值电压的定义得到了阈值电压的模型.该温度模型详细地研究了电势分布和阈值电压跟温度之间的变化关系,同时还近似地探讨了短沟道效应.为了进一步验证模型的正确性,利用SILVACO ATAS软件进行了相应的模拟.结果表明,模型计算与软件模拟吻合较好.     

全耗尽SOI MOSFETs阈值电压和电势分布的温度模型

提出了一个全耗尽SOI MOSFETs器件阈值电压和电势分布的温度模型. 基于近似的抛物线电势分布模型,利用适当的边界条件对二维的泊松方程进行求解. 同时利用阈值电压的定义得到了阈值电压的模型. 该温度模型详细地研究了电势分布和阈值电压跟温度之间的变化关系,同时还近似地探讨了短沟道效应. 为了进一步验证模型的正确性,利用SILVACO ATAS软件进行了相应的模拟. 结果表明,模型计算与软件模拟吻合较好.     

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.     

短沟Trench MOSFET阈值电压解析模型

传统MOS器件的阈值电压模型被广泛地用于分析Trench MOSFET的阈值电压,这种模型对于长沟道和均匀分布衬底的MOS器件来说很合适.但是对于Trench MOSFET器件来说却显现出越来越多的问题,这是因为Trench MOSFET的沟道方向是垂直的,其杂质分布也是非均匀的.本文基于二维电荷共享模型,给出了Trench MOSFET的一种新的阈值电压解析模型,该模型反映了器件的阈值电压随不同结构和工艺参数变化的规律,模型的结果和器件仿真软件Sivaco TCAD的仿真结果吻合较好.该模型较好地解决了以往所用的Trench MOSFET阈值电压模型计算不准确的问题.     

An Analytical Threshold Voltage Model for Fully Depleted SOI MOSFETs

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.     

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.     

深结短沟道MOS晶体管准二维阈值电压模型

提出了一个新的短沟道MOS晶体管表面势的准二维解析模型。不同于经典模型,该模型对沟道耗尽层横向剖分,由高斯定理导出沟道耗尽层电势的一维微分方程,方程考虑了漏、源的横向电场对沟道耗尽层厚度的影响。求解方程得到了耗尽层厚度与表面势的关系函数,由此得出了一个包含有沟道长度的阈值电压公式。通过MEDICI软件对多种不同参数的MOS晶体管进行了仿真,此模型计算结果与MEDICI仿真数据吻合较好,比电荷分享模型精度高。     

非均匀沟道DMOS器件阈值电压模型

提出了DMOS器件的二维电荷阈值电压模型。基于沟道区杂质的二维分布,求解泊松方 程,得到沟道区中耗尽电荷总量,给出DMOS二维阈值电压模型的解析式。该模型的解析解与实验 结果和数值解相吻合。并对DMOS的短沟效应和阈值电压与沟道表面扩散浓度、沟道结深和沟道 长度等参数的关系进行了深入分析,给出了短沟DMOS器件阈值电压的解析式。文中还给出了沟 道表面掺杂浓度在2.0×1016cm-3到10.0×1016cm-3范围内DMOS器件的阈值电压简明计算式。该 模型解决了习用的DMOS器件阈值电压模型解析值比实验结果大100％以上的问题。     

一种新的Halo掺杂圆柱围栅MOSFET阈值电压解析模型

通过在圆柱坐标系中精确求解泊松方程,建立了全新的Halo掺杂圆柱围栅MOSFET静电势,电场以及阈值电压的解析模型。与采用抛物线电势近似法得到的解析模型相比,当沟道半径远大于氧化层厚度时,新模型更为精确。模型还考虑了Halo区掺杂浓度、氧化层厚度以及沟道半径对器件阈值电压特性的影响。结果表明,采用中等程度的halo区掺杂浓度、较薄的栅氧化层以及较小的沟道半径可以有效改善器件的阈值电压特性。解析模型与三维数值模拟软件ISE所得结果高度吻合。     

Threshold voltages of SOI MuGFETs

The multiple-gate field-effect transistor (MuGFET) is a device with a gate folded on different sides of the channel region. They are one of the most promising technological solutions to create high-performance ultra-scaled SOI CMOS. In this work, the behavior of the threshold voltage in double-gate, triple-gate and quadruple-gate SOI transistors with different channel doping concentrations is studied through three-dimensional numerical simulation. The results indicated that for double-gate transistors, one or two threshold voltages can be observed, depending on the channel doping concentration. However, in triple-gate and quadruple-gate it is possible to observe up to four threshold voltages due to the corner effect and the different doping concentration between the top and bottom of the Fin.     

Modeling of ultrathin double-gate nMOS/SOI transistors

An analytical model valid near and below threshold is derived for double-gate nMOS/SOI devices. The model is based on Poisson's equation, containing both the doping impurity charges and the electron concentration. An original assumption of the constant difference between surface and mid-film potentials is successfully introduced. The model provides explicit expressions of the threshold voltage and threshold surface potential, which may no longer be assumed to be pinned at the limit of strong inversion, and demonstrates the nearly ideal subthreshold slope of ultrathin double-gate SOI transistors. Very good agreement with numerical simulations is observed. Throughout the paper we give an insight into weak inversion mechanisms occurring in thin double-gate structures     

Modeling of hetero-interface potential and threshold voltage for tied and separate nanoscale InAlAs-InGaAs symmetric double-gate HEMT

This paper presents an approximate solution of a 2-D Poisson’s equation in the channel region, based on physical correspondence between MOSFET and HEMT, with the approximation that the vertical channel potential distribution is a cubic function of position to study not only tied gate but separate gate bias conditions as well. An analytical expression for both front and back heterointerface potential is derived and threshold voltage is obtained iteratively from the proposed potential model. The threshold voltage behavior for tied and separated double-gate HEMT is investigated for various device dimensions. The back gate effect of the separated double gate HEMT is investigated for the depleted back channel only. The results obtained are verified by comparing them with simulated and experimental results.     

A new two-dimensional subthreshold behavior model for the short-channel asymmetrical dual-material double-gate (ADMDG) MOSFET’s

Based on the exact solution of two-dimensional Poisson’s equation, a novel subthreshold behavior model comprising channel potential, subthreshold swing, and threshold voltage for the short-channel asymmetrical dual-material double-gate (ADMDG) MOSFET’s have been developed. The model is verified by its simulation results that agree well with those of the two-dimensional numerical simulator. Besides offering the physical insight into device physics, the model provides the basic designing guidance for the ADMDG MOSFET’s.     

Two-dimensional analytical model of double-gate tunnel FETs with interface trapped charges including effects of channel mobile charge carriers

A two-dimensional analytical model of double-gate(DG) tunneling field-effect transistors(TFETs) with interface trapped charges is proposed in this paper. The influence of the channel mobile charges on the potential profile is also taken into account in order to improve the accuracy of the models. On the basis of potential profile, the electric field is derived and the expression for the drain current is obtained by integrating the BTBT generation rate. The model can be used to study the impact of interface trapped charges on the surface potential, the shortest tunneling length, the drain current and the threshold voltage for varying interface trapped charge densities, length of damaged region as well as the structural parameters of the DG TFET and can also be utilized to design the charge trapped memory devices based on TFET. The biggest advantage of this model is that it is more accurate, and in its expression there are no fitting parameters with small calculating amount. Very good agreements for both the potential, drain current and threshold voltage are observed between the model calculations and the simulated results.     

Analytical model for threshold voltage of double gate bilayer graphene field effect transistors

A new model for threshold voltage of double-gate Bilayer Graphene Field Effect Transistors (BLG-FETs) is presented in this paper. The modeling starts with deriving surface potential and the threshold voltage was modeled by calculating the minimum surface potential along the channel. The effect of quantum capacitance was taken into account in the potential distribution model. For the purpose of verification, FlexPDE 3D Poisson solver was employed. Comparison of theoretical and simulation results shows a good agreement. Using the proposed model, the effect of several structural parameters i.e. oxide thickness, quantum capacitance, drain voltage, channel length and doping concentration on the threshold voltage and surface potential was comprehensively studied.     

A simple model for threshold voltage of surrounding-gate MOSFET's

We propose a threshold voltage model for surrounding-gate MOSFETs. The model treats the ends and the double-gate regions of the channel as separate devices operating in parallel. The threshold voltage for the full device is obtained as the perimeter-weighted sum of the threshold voltages of the two parts enabling simple analytic threshold models to be used. Short channel effects and drain-induced barrier lowering are also modeled in this manner     

Compact Analytical Model of Double Gate Junction-less Field Effect Transistor Comprising Quantum-Mechanical Effect

We investigate the quantum-mechanical effects on the electrical properties of the double-gate junctionless field effect transistors. The quantum-mechanical effect, or carrier energy-quantization effects on the threshold voltage, of DG-JLFET are analytically modeled and incorporated in the Duarte et al. model and then verified by TCAD simulation.     

Bias temperature reliability of p-channel high-voltage devices

Important shifts in the threshold voltage of high voltage p-channel DMOS transistors have been observed. These shifts are strongly dependent on the stress conditions.An empirical degradation model is derived from measurement data. For a given allowed shift in threshold voltage, this model can determine the safe operating area of the device.The shift in threshold voltage in the p-channel DMOS transistors is explained by excitation and trapping of holes at the oxide-silicon interface at the drain side.     

Process/physics-based threshold voltage model for nano-scaled double-gate devices

Compact physics/process-based model for threshold voltage in double-gate devices is presented. Predominant short-channel effects for double-gate devices, which are drain-induced barrier lowering (DIBL) and short-channel-induced barrier lowering (SCIBL), are physically analysed and modeled to be applicable to SPICE-compatible circuit simulators. The short-channel models are also developed for bulk-Si device and compared to those of double-gate devices. The validity and predictability of the models are demonstrated and confirmed by numerical device simulation results for extremely scaled L _eff = 25?nm double-gate devices and bulk-Si device.