The study on two-dimensional analytical model for gate stack fully depleted strained Si on silicon-germanium-on-insulator MOSFETs

Based on the exact resultant solution of two-dimensional Poisson's equation in strained Si and Si_{1 - X}Ge_X layer, a simple and accurate two-dimensional analytical model including surface channel potential, surface channel electric field, threshold voltage and subthreshold swing for fully depleted gate stack strained Si on silicon-germanium-on-insulator (SGOI) MOSFETs has been developed. The results show that this novel structure can suppress the short channel effects (SCE), the drain-induced barrier-lowering (DIBL) and improve the subthreshold performance in nanoelectronics application. The model is verified by numerical simulation. The model provides the basic designing guidance of gate stack strained Si on SGOI MOSFETs.     

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.     

Two-dimensional analytical subthreshold model of graded channel DG FD SOI n-MOSFET with gate misalignment effect

A two-dimensional (2-D) analytical subthreshold model is developed for a graded channel double gate (DG) fully depleted SOI n-MOSFET incorporating a gate misalignment effect. The conformal mapping transformation (CMT) approach has been used to provide an accurate prediction of the surface potential, electric field, threshold voltage and subthreshold behavior of the device, considering the gate misalignment effect to be on both source and drain side. The model is applied to both uniformly doped (UD) and graded channel (GC) DG MOSFETs. The results of an analytical model agree well with 3-D simulated data obtained by ATLAS-3D device simulation software.     

A two-dimensional analytical analysis of subthreshold behavior to study the scaling capability of nanoscale graded channel gate stack DG MOSFETs

In this paper, a new nanoscale graded channel gate stack (GCGS) double-gate (DG) MOSFET structure and its 2-D analytical model have been proposed, investigated and expected to suppress the short-channel-effects (SCEs) and improve the subthreshold performances for nanoelectronics applications. The model predicts a shift, increasing potential barrier, in the surface potential profile along the channel, which ensures a reduced threshold voltage roll-off and DIBL effects. In the proposed structure, the subthreshold current and subthreshold swing characteristics are greatly improved in comparison with the conventional DG MOSFETs. The developed approaches are verified and validated by the good agreement found with the numerical simulation. (GCGS) DG MOSFET can alleviate the critical problem and further improve the immunity of SCEs of CMOS-based devices in the nanoscale regime.     

异质多晶SiGe栅应变Si NMOSFET物理模型研究

结合了“栅极工程”和“应变工程”二者的优点, 异质多晶SiGe栅应变Si MOSFET, 通过沿沟道方向使用不同功函数的多晶SiGe材料, 在应变的基础上进一步提高了MOSFET的性能. 本文结合其结构模型, 以应变Si NMOSFET为例, 建立了强反型时的准二维表面势模型, 并进一步获得了其阈值电压模型以及沟道电流的物理模型. 应用MATLAB对该器件模型进行了分析, 讨论了异质多晶SiGe栅功函数及栅长度、衬底SiGe中Ge组分等参数对器件阈值电压、沟道电流的影响, 获得了最优化的异质栅结构. 模型所得结果与仿真结果及相关文献给出的结论一致, 证明了该模型的正确性. 该研究为异质多晶SiGe栅应变Si MOSFET的设计制造提供了有价值的参考. 关键词： 异质多晶SiGe栅 应变Si NMOSFET 表面势 沟道电流     

Two-dimensional models of threshold voltage and subthreshold current for symmetrical double-material double-gate strained Si MOSFETs

The two-dimensional models for symmetrical double-material double-gate(DM-DG) strained Si(s-Si) metal–oxide semiconductor field effect transistors(MOSFETs) are presented. The surface potential and the surface electric field expressions have been obtained by solving Poisson's equation. The models of threshold voltage and subthreshold current are obtained based on the surface potential expression. The surface potential and the surface electric field are compared with those of single-material double-gate(SM-DG) MOSFETs. The effects of different device parameters on the threshold voltage and the subthreshold current are demonstrated. The analytical models give deep insight into the device parameters design. The analytical results obtained from the proposed models show good matching with the simulation results using DESSIS.     

高k介质异质栅全耗尽SOI MOSFET二维解析模型

为了研究高介电常数(高k)栅介质材料异质栅中绝缘衬底上的硅和金属-氧化物-硅场效应晶体管的短沟道效应,为新结构器件建立了全耗尽条件下表面势和阈值电压的二维解析模型.模型中考虑了各种主要因素的影响,包括不同介电常数材料的影响,栅金属长度及其功函数变化的影响,不同漏电压对短沟道效应的影响.结果表明,沟道表面势中引入了阶梯分布,因此源端电场较强;同时漏电压引起的电势变化可以被屏蔽,抑制短沟道效应.栅介电常数增大,也可以较好的抑制短沟道效应.解析模型与数值模拟软件ISE所得结果高度吻合. 关键词： 异质栅 绝缘衬底上的硅 阈值电压 解析模型     

非对称Halo异质栅应变Si SOI MOSFET的二维解析模型

为了进一步提高深亚微米SOI (Silicon-On-Insulator) MOSFET (Metal-Oxide Semiconductor Field Effect Transistor) 的电流驱动能力, 抑制短沟道效应和漏致势垒降低效应, 提出了非对称Halo异质栅应变Si SOI MOSFET. 在沟道源端一侧引入高掺杂Halo结构, 栅极由不同功函数的两种材料组成. 考虑新器件结构特点和应变的影响, 修正了平带电压和内建电势. 为新结构器件建立了全耗尽条件下的表面势和阈值电压二维解析模型. 模型详细分析了应变对表面势、表面场强、阈值电压的影响, 考虑了金属栅长度及功函数差变化的影响. 研究结果表明,提出的新器件结构能进一步提高电流驱动能力, 抑制短沟道效应和抑制漏致势垒降低效应, 为新器件物理参数设计提供了重要参考. 关键词： 非对称Halo 异质栅 应变Si 短沟道效应     

Fabrication of Ge-channel MOSFETs by using replacement gate process and selective epitaxial growth

We fabricated Ge-channel metal-oxide-semiconductor field-effect transistors (MOSFETs) by using replacement gate process and selective epitaxial growth. In our method, thin Ge layers were selectively grown on the channel region of MOSFETs after the removal of a sacrificial gate stack structure and the etching of the channel region. Ge layers with a smooth surface and a good morphology could be obtained by using the thin Si_0.5Ge_0.5 buffer layer. Dislocations were observed in the epitaxial layers and near the interface between the epitaxial layer and the substrates. We consider that these dislocations degrade the device performance. Although the electrical characteristics of the obtained MOSFETs need further improvement, our method is one of the promising candidates for the practical fabrication process of Ge-channel MOSFETs.     

The influence and explanation of fringing-induced barrier lowering on sub-100 nm MOSFETs with high-k gate dielectrics

The fringing-induced barrier lowering(FIBL) effect of sub-100 nm MOSFETs with high-k gate dielectrics is investigated using a two-dimensional device simulator.An equivalent capacitance theory is proposed to explain the physics mechanism of the FIBL effect.The FIBL effect is enhanced and the short channel performance is degraded with increasing capacitance.Based on equivalent capacitance theory,the influences of channel length,junction depth,gate/lightly doped drain(LDD) overlap length,spacer material and spacer width on FIBL is thoroughly investigated.A stack gate dielectric is presented to suppress the FIBL effect.     

Physics of fluctuation processes in downscaled silicon MOSFETs

Physical mechanics of fluctuation processes in advanced submicron and decananometer MOSFETs (metal-oxide-semiconductor field-effect transistors) including the ultra-thin film SOI (siliconon-insulator) devices using strained silicon films are reviewed. The review is substantially based on the results obtained by the authors. It is shown that the following drastic changes occur in the nature and parameters of noise in such devices as a result of their downscaling when the gate oxide thickness and the channel length and width are decreased, the SOI substrates are used, the silicon film thickness is reduced, the film doping level is varied, the strained silicon films are employed, etc. Firstly, the Lorentzian components can appear in the current noise spectra. Those components are due to (i) electron tunneling from the valence band through the gate oxide in the SOI MOSFETs of a sufficiently thin gate oxide (LKE-Lorentzians); (ii) Nyquist fluctuations generated in the source and drain regions near the back Si/SiO₂ interface in the SOI MOSFETs (BGI Lorentzians); (iii) electron exchange between the channel and some single trap in the gate oxide of the transistors with sufficiently small length and width of the channel (RTS Lorentzians). Secondly, the 1/f-noise level can increase due to (i) the appearance of recombination processes near the Si/SiO₂ interface activated by the currents of electron tunneling from the valence band; (ii) an increase in the trap density in the gate oxide of the devices fabricated on the biaxially tensile-strained silicon films; (iii) the contribution of the 1/f fluctuations of the current flowing through the gate oxide as a result of electron tunneling from the conduction band. At the same time, the 1/f-noise level may decrease due to a decrease in the trap density in the gate oxide of the transistors fabricated on the uniaxially tensile-strained silicon films. Moreover, a 1/f ^1.7 component may appear in the noise spectra for the transistors of a sufficiently thin gate oxide, whose component is due to charge fluctuations on the defects located near the interface between the gate polysilicon and the gate oxide.     

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.     

Ge metal oxide semiconductor field effect transistors with optimized Si cap and HfSiO2 high-k metal gate stacks

High mobility metal-oxide-semiconductor-field-effect-transistors (MOSFETs) are demonstrated on high quality epitaxial Si_0.75Ge_0.25 films selectively grown on Si (100) substrates. With a Si cap processed on Si_0.75Ge_0.25 channels, HfSiO₂ high-k gate dielectrics exhibited low C–V hysteresis (<10 mV), interface trap density (7.5 × 10¹⁰), and gate leakage current (∼10⁻²A/cm² at an EOT of 13.4 Å), which are comparable to gate stack on Si channels. The mobility enhancement afforded intrinsically by the Si_0.75Ge_0.25 channel (60%) is further increased by a Si cap (40%) process, resulting in a combined ∼100% enhancement over Si channels. The Si cap process also mitigates the low potential barrier issues of Si_0.75Ge_0.25 channels, which are major causes of the high off-state current of small band gap energy Si_0.75Ge_0.25 pMOSFETs, by improving gate control over the channel.     

Poly-Si1-xGex栅应变SiN型金属-氧化物-半导体场效应管栅耗尽模型研究

基于对Poly-Si_1-xGe_x栅功函数的分析,通过求解Poisson方程, 获得了Poly-Si_1-xGe_x栅应变Si N型金属-氧化物-半导体场效应器件 (NMOSFET)垂直电势与电场分布模型.在此基础上,建立了考虑栅耗尽的Poly-Si_1-xGe_x栅应变Si NMOSFET的阈值电压模型和栅耗尽宽度及其归一化模型,并利用该模型,对器件几何结构参数、 物理参数尤其是Ge组分对Poly-Si_1-xGe_x栅耗尽层宽度的影响, 以及栅耗尽层宽度对器件阈值电压的影响进行了模拟分析.结果表明:多晶耗尽随Ge组分和栅掺杂浓度的增加而减弱, 随衬底掺杂浓度的增加而增强;此外,多晶耗尽程度的增强使得器件阈值电压增大. 所得结论能够为应变Si器件的设计提供理论依据.     

应变SiGe p 型金属氧化物半导体场效应管栅电容特性研究

由于台阶的出现, 应变SiGe p型金属氧化物半导体场效应管 (pMOSFET) 的栅电容特性与体Si器件的相比呈现出很大的不同, 且受沟道掺杂的影响严重. 本文在研究应变SiGe pMOSFET器件的工作机理及其栅电容C-V 特性中台阶形成机理的基础上, 通过求解器件不同工作状态下的电荷分布, 建立了应变SiGe pMOSFET栅电容模型, 探讨了沟道掺杂浓度对台阶的影响. 与实验数据的对比结果表明, 所建立模型能准确反映应变SiGe pMOSFET器件的栅电容特性, 验证了模型的正确性. 该理论为Si基应变金属氧化物半导体(MOS)器件的设计制造提供了重要的指导作用, 并已成功应用于Si基应变器件模型参数提取软件中, 为Si基应变MOS的仿真奠定了理论基础. 关键词： 应变SiGe pMOSFET 栅电容特性 台阶效应 沟道掺杂     

单轴应变Si NMOSFET热载流子栅电流模型

热载流子效应产生的栅电流是影响器件功耗及可靠性的重要因素之一,本文基于热载流子形成的物理过程,建立了单轴应变硅NMOSFET热载流子栅电流模型,并对热载流子栅电流与应力强度、沟道掺杂浓度、栅源电压、漏源电压等的关系,以及TDDB(经时击穿)寿命与栅源电压的关系进行了分析研究.结果表明,与体硅器件相比,单轴应变硅MOS器件不仅具有较小的热载流子栅电流,而且可靠性也获得提高.同时模型仿真结果与单轴应变硅NMOSFET的实验结果符合较好,验证了该模型的可行性.     

Analytical modeling of subthreshold current and subthreshold swing of short-channel triple-material double-gate (TM-DG) MOSFETs

An analytical model for subthreshold current and subthreshold swing of short-channel triple-material double-gate (TM-DG) MOSFETs is presented in this paper. Both the drift and diffusion components of current densities are considered for the modeling of subthreshold current. Virtual cathode concept of DG MOSFETs is utilized to model the subthreshold swing of TM-DG MOSFETs. The effect of different length ratios of the three channel regions under three different gate materials of device on the subthreshold current and subthreshold swing of the short-channel TM-DG MOSFETs have been discussed. The dependencies of subthreshold current and subthreshold swing on various device parameters have been studied. The simulation data obtained by using the commercially available 2D device simulation software ATLAS™ has been used to validate the present model.     

Channel length scaling and the impact of metal gate work function on the performance of double gate-metal oxide semiconductor field-effect transistors

In this paper, we study the effects of short channel on double gate MOSFETs. We evaluate the variation of the threshold voltage, the subthreshold slope, the leakage current and the drain-induced barrier lowering when channel length L _CH decreases. Furthermore, quantum effects on the performance of DG-MOSFETs are addressed and discussed. We also study the influence of metal gate work function on the performance of nanoscale MOSFETs. We use a self-consistent Poisson-Schrödinger solver in two dimensions over the entire device. A good agreement with numerical simulation results is obtained.     

Analytical modeling and simulation of subthreshold characteristics of back-gated SSGOI and SSOI MOSFETs: A comparative study

The Silicon–Germanium-on-Insulator (SGOI) and Silicon-on-Insulator (SOI) based MOS structures are spearheading the strained-Si technology. The present work compares the subthreshold characteristics of two short-channel back-gated (BG) strained-Si-on-SGOI (SSGOI) and BG strained-Si-on-Insulator (SSOI) MOSFETs, and provides some solutions to overcome the degradation in subthreshold characteristics with the unrelenting downscaling of the devices. Subthreshold behaviors of the MOS structures are based on surface potential model which is determined by solving the 2D Poisson's equation with suitable boundary conditions by evanescent mode analysis for both of the MOS structures. The closed form expressions for threshold voltage, subthreshold current and subthreshold swing have been derived for symmetrical as well as independent gate operation (IGO). In addition, the Electrostatic integrity (EI) factors for SSOI and SSGOI MOS structures have been estimated and compared with Double-Gate (DG) MOSFET. The numerical simulation results, obtained by ATLAS?, a 2D device simulator from Silvaco, have been used to assess the validity of the models.     

Ultrathin gate dielectrics for silicon nanodevices

This paper reviews recent progress in structural and electronic characterizations of ultrathin SiO₂thermally grown on Si(100) surfaces and applications of such nanometer-thick gate oxides to advanced MOSFETs and quantum-dot MOS memory devices. Based on an accurate energy band profile determined for the n ⁺ -poly- Si/SiO₂/Si(100) system, the measured tunnel current through ultrathin gate oxides has been quantitatively explained by theory. From the detailed analysis of MOSFET characteristics, the scaling limit of gate oxide thickness is found to be 0.8 nm. Novel MOSFETs with a silicon quantum-dot floating gate embedded in the gate oxide have indicated the multiple-step electron injection to the dot, being interpreted in terms of Coulombic interaction among charged dots.