高k栅介质MOSFETs的二维阈值电压模型

给出包括栅电介质与耗尽层区域的边界条件和二维沟道电势分布.根据这个电势分布,得出高k栅介质MOSFET的阈值电压模型,模型中考虑短沟道效应和高k栅介质的边缘场效应.模型模拟结果和实验结果能够很好地符合.通过和一个准二维模型的结果相比较,表明该模型更准确.另外,还详细讨论了影响高k栅电介质MOSFET阈值电压的一些因素.     

A 2-D analytical threshold-voltage model for GeOI/GeON MOSFET with high-k gate dielectric

A 2-D analytical threshold-voltage model for ultra-thin-body MOSFET with buried insulator and high-k gate dielectric is established by solving the 2-D Poisson's equation for the gate-dielectric, channel and buried-insulator regions. The validity of the model is confirmed by comparing with experimental data and other models. Using the model, the influences of gate-dielectric permittivity, buried-insulator permittivity, channel thickness, buried-insulator thickness and channel doping concentration on threshold behaviors are investigated. It is found that the threshold behaviors can be improved by using buried insulator with low permittivity, thin channel and high channel doping concentration. However, the threshold performance would be degraded when high-k gate dielectric is used due to enhanced fringing-field effect.     

Influence of sidewall spacer on threshold voltage of MOSFET with high-k gate dielectric

In this paper, an analytical expression of the gate-dielectric fringing-potential distribution is derived for high-k gate-dielectric MOSFET through a conformal-mapping transformation method for the first time. Based on the fringing-potential distribution, the threshold-voltage model of the MOSFET is improved, and the influence of sidewall spacer on the threshold voltage is discussed in detail. Calculated results indicate that low-k sidewall spacer can alleviate the fringing-field effect.     

A 2D threshold-voltage model for small MOSFET with quantum-mechanical effects

A threshold condition different from the classical one is proposed for MOSFET with quantum effects, and is based on self-consistent numerical solution of the Schrödinger’s and Poisson’s equations. Furthermore, an accurate 1D threshold-voltage model including polysilicon-depletion effects is built by experimental fitting. Simulated results exhibit good agreement with measurement data. Based on this 1D model, a 2D quantum-modified threshold-voltage model for small MOSFET is developed by solving the quasi-2D Poisson’s equation and taking short-channel effects and quantum-mechanical effects into consideration. The model can also be used for deep-submicron MOSFET with high-k gate-dielectric and reasonable design of device parameters.     

双栅肖特基源漏MOSFET的阈值电压模型

通过求解泊松方程得到了双栅肖特基势垒MOSFET的解析模型. 这个解析模型包括整个沟道的准二维电势分布和适用于短沟双栅肖特基势垒MOSFET的阈值电压模型.数值模拟器ISE DESSIS验证了模型结果.     

双栅肖特基源漏MOSFET的阈值电压模型

通过求解泊松方程得到了双栅肖特基势垒MOSFET的解析模型. 这个解析模型包括整个沟道的准二维电势分布和适用于短沟双栅肖特基势垒MOSFET的阈值电压模型.数值模拟器ISE DESSIS验证了模型结果.     

Gate current modeling and optimal design of nanoscale non-overlapped gate to source/drain MOSFET

A novel nanoscale MOSFET with a source/drain-to-gate non-overlapped and high-k spacer structure has been demonstrated to reduce the gate leakage current for the first time.The gate leakage behaviour of the novel MOSFET structure has been investigated with the help of a compact analytical model and Sentaurus simulation. A fringing gate electric field through the dielectric spacer induces an inversion layer in the non-overlap region to act as an extended S/D(source/drain) region.It is found that an optimal source/drain-to-gate non-overlapped and high-A:spacer structure has reduced the gate leakage current to a great extent as compared to those of an overlapped structure.Further,the proposed structure had improved off current,subthreshold slope and drain induced barrier lowering(DIBL) characteristics.It is concluded that this structure solves the problem of high leakage current without introducing extra series resistance.     

Gate Current Modeling and Optimal Design of Nanoscale Non-Overlapped Gate to Source/Drain MOSFET

In this paper, novel nanoscale MOSFET with Source/Drain-to-Gate Non-overlapped and high-k spacer structure has been demonstrated to reduce the gate leakage current for the first time. The gate leakage behaviour of novel MOSFET structure has been investigated with help of compact analytical model and Sentaurus Simulation. Fringing gate electric field through the dielectric spacer induces inversion layer in the non-overlap region to act as extended S/D region. It is found that optimal Source/Drain-to-Gate Non-overlapped and high-k spacer structure has reduced the gate leakage current to great extent as compared to those of an overlapped structure. Further, the proposed structure had improved off current, subthreshold slope and DIBL characteristic. It is concluded that this structure solves the problem of high leakage current without introducing the extra series resistance.     

Compact modeling of the effects of parasitic internal fringe capacitance on the threshold voltage of high-k gate-dielectric nanoscale SOI MOSFETs

A compact model for the effect of the parasitic internal fringe capacitance on the threshold voltage of high-k gate-dielectric silicon-on-insulator MOSFETs is developed. The authors' model includes the effects of the gate-dielectric permittivity, spacer oxide permittivity, spacer width, gate length, and the width of an MOS structure. A simple expression for the parasitic internal fringe capacitance from the bottom edge of the gate electrode is obtained and the charges induced in the source and drain regions due to this capacitance are considered. The authors demonstrate an increase in the surface potential along the channel due to these charges, resulting in a decrease in the threshold voltage with an increase in the gate-dielectric permittivity. The accuracy of the results obtained using the authors' analytical model is verified using two-dimensional device simulations.     

Gate leakage properties of MOS devices with tri-layer high-k gate dielectric

Gate leakage of deep-submicron MOSFET with stack high-k dielectrics as gate insulator is studied by building a model of tunneling current. Validity of the model is checked when it is used for MOSFET with SiO₂ and high-k dielectric material as gate dielectrics, respectively, and simulated results exhibit good agreement with experimental data. The model is successfully used for a tri-layer gate-dielectric structure of HfON/HfO₂/HfSiON with a U-shape nitrogen profile and a like-Si/SiO₂ interface, which is proposed to solve the problems of boron diffusion into channel region and high interface-state density between Si and high-k dielectric. By using the model, the optimum structural parameters of the tri-layer dielectric can be determined. For example, for an equivalent oxide thickness of 2.0 nm, the tri-layer gate-dielectric MOS capacitor with 0.3-nm HfON, 0.5-nm HfO₂ and 1.2-nm HfSiON exhibits the lowest gate leakage.     

A new grounded lamination gate (GLG) for diminished fringe-capacitance effects in high-/spl kappa/ gate-dielectric MOSFETs

A grounded lamination gate (GLG) structure for high-/spl kappa/ gate-dielectric MOSFETs is proposed, with grounded metal plates in the spacer oxide region. Two-dimensional device simulations performed on the new structure demonstrate a significant improvement with respect to the threshold voltage roll-off with increasing gate-dielectric constant (due to parasitic internal fringe capacitance), keeping the equivalent oxide thickness same. A simple fabrication procedure for the GLG MOSFET is also presented.     

La基高k栅介质的研究进展

SiO2作为栅介质已无法满足MOSFET器件高集成度的需求,高k栅介质材料成为当前研究的热点。综述了高k栅介质材料应当满足的各项性能指标和研究意义,总结了La基高k栅介质材料的最新研究进展,以及在改正自身缺点时使用的一些实验方法,指出了有可能成为下一代MOSFET栅介质的几种La基高k材料。La基高k材料的研究为替代SiO2的芯片制造工艺提供优异的候选材料及理论指导,这是一项当务之急且浩大的工程。     

高K栅堆叠结构MOSFET器件阈值电压不稳定度的半经验解析模型

A semi-empirical analytic model for the threshold voltage instability of MOSFET is derived from the Shockley-Read-Hall (SRH) statistics in this paper to account for the transient charging effects in a MOSFET high-k gate stack. Starting from the single energy level and single trap assumption, an analytical expression of the filled trap density in terms of the dynamic time is derived from the SRH statistics. The semi-empirical analytic model of the threshold voltage instability is developed based on the MOSFET device physics between the threshold voltage and the induced trap density. The obtained model is also verified by the extensive experimental data of the trapping and de-trapping stress from the different high k gate configuration.     

Mobility measurement and degradation mechanisms of MOSFETs made with ultrathin high-k dielectrics

Accurate measurements and degradation mechanisms of the channel mobility for MOSFETs with HfO/sub 2/ as the gate dielectric have been systematically studied in this paper. The error in mobility extraction caused by a high density of interface traps for a MOSFET with high-k gate dielectric has been analyzed, and a new method to correct this error has been proposed. Other sources of error in mobility extraction, including channel resistance, gate leakage current, and contact resistance for a MOSFET with ultrathin high-k dielectric have also been investigated and reported in this paper. Based on the accurately measured channel mobility, we have analyzed the degradation mechanisms of channel mobility for a MOSFET with HfO/sub 2/ as the gate dielectric. The mobility degradation due to Coulomb scattering arising from interface trapped charges, and that due to remote soft optical phonon scattering are discussed.     

Modeling of Gate Current and Capacitance in Nanoscale-MOS Structures

By applying a fully self-consistent solution of the Schrodinger-Poisson equations, a simple unified approach has been developed in order to study the gate current and gate capacitance of nanoscale-MOS structures with ultrathin dielectric layer. In this paper, the model has been employed to investigate various gate structure and material combinations, thereby demonstrating wide applicability of the present model in the design of nanoscale-MOSFET devices. The results obtained by applying the proposed model are in good agreement with experimental data and previous models in the literature. A new result concerning optimum nitrogen content in HfSiON high-k gate-dielectric structure reported in this paper requires experimental verification through device fabrication     

Analytical modeling for 3D potential distribution of rectangular gate (RecG) gate-all-around (GAA) MOSFET in subthreshold and strong inversion regions

In this paper, we have introduced an analytical subthreshold and strong inversion 3D potential model for rectangular gate (RecG) gate-all-around (GAA) MOSFET. The subthreshold and strong inversion potential distribution in channel region of a RecG MOSFET is obtained respectively by solving 3D Laplace and 3D Poisson equations. The assumed parabolic potential distribution along the z-axis in channel direction is appropriately matched with 3D device simulator after consideration of z-depended characteristic length in subthreshold region. For accurate estimation of short channel effects (SCE), the electrostatics near source and drain is corrected. The precise gate-to-gate potential distribution is obtained after consideration of higher order term in assumed parabolic potential profile. The model compares well with numerical data obtained from the 3D ATLAS as a device simulator and deckbuild as an interactive runtime of Silvaco Inc.     

Modeling and estimation of edge direct tunneling current for nanoscale metal gate (Hf/AlNx) symmetric double gate MOSFET

This paper present, the modeling and estimation of edge direct tunneling current of metal gate (Hf/AlN_x) symmetric double gate MOSFET with an intrinsic silicon channel. To model this leakage current, we use the surface potential model obtained from 2D analytical potential model for double gate MOSFET. The surface potential model is used to evaluate the electric field across the insulator layer hence edge direct tunneling current. Further, we have modeled and estimated the edge direct tunneling leakage current for high-k dielectric. In this paper, from our analysis, it is found that dual metal gate (Hf/AlN_x) material offer the optimum leakage currents and improve the performance of the device. This feature of the device can be utilized in low power and high performance circuits and systems.     

Double-Gate Tunnel FET With High-κ Gate Dielectric

In this paper, we propose and validate a novel design for a double-gate tunnel field-effect transistor (DG tunnel FET), for which the simulations show significant improvements compared with single-gate devices using a gate dielectric. For the first time, DG tunnel FET devices, which are using a high-gate dielectric, are explored using realistic design parameters, showing an on-current as high as 0.23 mA for a gate voltage of 1.8 V, an off-current of less than 1 fA (neglecting gate leakage), an improved average subthreshold swing of 57 mV/dec, and a minimum point slope of 11 mV/dec. The 2D nature of tunnel FET current flow is studied, demonstrating that the current is not confined to a channel at the gate-dielectric surface. When varying temperature, tunnel FETs with a high-kappa gate dielectric have a smaller threshold voltage shift than those using SiO₂, while the subthreshold slope for fixed values of V_g remains nearly unchanged, in contrast with the traditional MOSFET. Moreover, an I_on/I_off ratio of more than 2 times 10¹¹ is shown for simulated devices with a gate length (over the intrinsic region) of 50 nm, which indicates that the tunnel FET is a promising candidate to achieve better-than-ITRS low-standby-power switch performance.     

Overview and status of metal S/D Schottky-barrier MOSFET technology

In this paper, the metal source/drain (S/D) Schottky-barrier (SB) MOSFET technology is reviewed. The technology offers several benefits that enable scaling to sub-30-nm gate lengths including extremely low parasitic S/D resistance (1% of the total device resistance), atomically abrupt junctions that enable the physical scaling of the device to sub-10-nm gate lengths, superior control of OFF-state leakage current due to the intrinsic Schottky potential barrier, and elimination of parasitic bipolar action. These and other benefits accrue using a low-thermal-budget CMOS manufacturing process requiring two fewer masks than conventional bulk CMOS. The SB-CMOS manufacturing process enables integration of critical new materials such as high-k gate insulators and strained silicon substrates. SB MOSFET technology state of the art is also reviewed, and shown to be focused on barrier-height-lowering techniques that use interfacial layers between the metal S/Ds and the channel region. SB-PMOS devices tend to have superior performance compared to NMOS, but NMOS performance has recently improved by using ytterbium silicide or by using hybrid structures that incorporate interfacial layers to lower the SB height.     

高k介质阶梯变宽度SOI LDMOS

本文提出了一种具有高k介质阶梯变宽度结构的新型的SOI LDMOS器件,该器件通过在漂移区内引入介质区域使得漂移区的宽度呈阶梯变化.借助三维器件仿真软件DAVINCI对其势场分布及耐压特性进行了深入分析.首先,阶梯变宽度结构能够在漂移区内引入新的电场峰值来优化势场分布,提高击穿电压.其次,采用高k材料作为侧壁介质区域可以进一步优化漂移区内势场分布,并提高漂移区浓度来降低导通电阻.结果表明,与常规结构相比,新器件的击穿电压可提高42%,导通电阻可降低37.5%,其FOM优值是常规器件的3.2倍.