亚100nm SOI器件的结构优化分析

分析了SOI器件各结构参数对器件性能的影响,给出了器件各结构参数的优化方向,找出了可行硅膜厚度和可行沟道掺杂浓度之间的设计容区.在部分耗尽与全耗尽SOI器件的交界处,阈值电压的漂移有一个峰值,在器件设计时应避免选用这一交界区.此外,随着硅膜厚度的减小,器件的泄漏电流随着沟道掺杂浓度的不同,有一个极小值.通过模拟分析发现,只要合理选择器件的结构参数,就能得到性能优良的SOI器件.     

亚100nm SOI器件的结构优化分析

分析了SOI器件各结构参数对器件性能的影响,给出了器件各结构参数的优化方向,找出了可行硅膜厚度和可行沟道掺杂浓度之间的设计容区.在部分耗尽与全耗尽SOI器件的交界处,阈值电压的漂移有一个峰值,在器件设计时应避免选用这一交界区.此外,随着硅膜厚度的减小,器件的泄漏电流随着沟道掺杂浓度的不同,有一个极小值.通过模拟分析发现,只要合理选择器件的结构参数,就能得到性能优良的SOI器件     

部分耗尽SOI MOSFETs中沟道的非对称掺杂效应

利用二维模拟软件对部分耗尽SoI器件中的非对称掺杂沟道效应进行了模拟.详细地研究了该结构器件的电学性能,如输出特性,击穿特性.通过本文模拟发现部分耗尽SOI非对称掺杂沟道相比传统的部分耗尽SOI,能抑制浮体效应,改善器件的击穿特性.同时跟已有的全耗尽SOI非对称掺杂器件相比,部分耗尽器件性能随参数变化,在工业应用上具有可预见性和可操作性.因为全耗尽器件具有非常薄的硅膜,而这将引起如前栅极跟背栅极的耦合效应和热电子退化等寄生效应.     

部分耗尽SOI MOSFETs中沟道的非对称掺杂效应

利用二维模拟软件对部分耗尽SoI器件中的非对称掺杂沟道效应进行了模拟.详细地研究了该结构器件的电学性能,如输出特性,击穿特性.通过本文模拟发现部分耗尽SOI非对称掺杂沟道相比传统的部分耗尽SOI,能抑制浮体效应,改善器件的击穿特性.同时跟已有的全耗尽SOI非对称掺杂器件相比,部分耗尽器件性能随参数变化,在工业应用上具有可预见性和可操作性.因为全耗尽器件具有非常薄的硅膜,而这将引起如前栅极跟背栅极的耦合效应和热电子退化等寄生效应.     

Ultra-Thin Body SOI MOSFET交流特性分析和结构优化

针对沟道长度为50nm的UTB SOI器件进行了交流模拟工作,利用器件主要的性能参数,详细分析了UTB结构的交流特性.通过分析UTB SOI器件的硅膜厚度、侧墙宽度等结构参数对器件交流特性的影响,对器件结构进行了优化.最终针对UTB SOI MOSFET结构提出了一种缓解速度和功耗特性优化之间矛盾的方法,从而实现了结构参数的优化选取,使UTB SOI MOSFET器件的应用空间更为广泛.     

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.     

全耗尽SOI器件源/漏区抬升结构的形成（英文）

介绍了在全耗尽绝缘体上硅(FDSOI)结构上,通过在SOI表面外延生长形成金属氧化物半导体场效应晶体管(MOSFET)源/漏区抬升结构的方法。研究了不同的工艺参数对外延生长的影响,从而在合适的掺杂浓度下得到均匀的外延生长形貌。提出了两种新的途径来控制SOI的厚度:采用一种新的方法生长垫氧层,以及在源漏区外延生长前,在衬底外延生长硅薄膜层,从而补偿工艺导致的SOI损耗。这两种新的方法使SOI厚度增加了约5 nm。工艺优化后的FDSOI器件沟道厚度约为6 nm,源漏外延层厚度为20～30 nm。最后,阐述了外延成分对器件电学性能的影响。     

Ultra-Thin Body SOI MOSFET交流特性分析和结构优化

针对沟道长度为50nm的UTB SOI器件进行了交流模拟工作，利用器件主要的性能参数，详细分析了UTB结构的交流特性．通过分析UTB SOI器件的硅膜厚度、侧墙宽度等结构参数对器件交流特性的影响，对器件结构进行了优化．最终针对UTB SOI MOSFET结构提出了一种缓解速度和功耗特性优化之间矛盾的方法，从而实现了结构参数的优化选取，使UTB SOI MOSFET器件的应用空间更为广泛．     

SOI和体硅MOSFET大信号非准静态效应比较研究

研究了全耗尽SOI、部分耗尽SOI和体硅NMOS器件中源、漏、栅和衬底电流的非准静态现象。研究表明,在相同的结构参数下,体硅器件的非准静态效应最强,PDSOI次之,FDSOI最弱。指出了沟道源、漏端反型时间和反型程度的不同是造成非准静态效应的内在原因。最后提出临界升压时间的概念,以此对非准静态效应进行定量表征,深入研究器件结构参数对非准静态效应的影响规律。结果显示,通过缩短沟道长度、降低沟道掺杂浓度、减小硅膜厚度和栅氧厚度、提高埋氧层厚度等手段,可以弱化SOI射频MOS器件中的非准静态效应。     

Unified MOSFET Short Channel Factor Using Variational Method

It is well known that short channel effect is one of the most important constraints that determine the downscaling of MOSFET's.The relationship between the device structure configuration and short channel effect is first expressed empirically in Ref.[1].And recently,due to...     

Unified MOSFET Short Channel Factor Using Variational Method

A new natural gate length scale for MOSFET's is presented using Variational Method. Comparison of the short channel effects is conducted for the uniform channel doping bulk MOSFET, intrinsic channel doping bulk MOSFET, SOI MOSFET and double gated MOSFET. And the results are verified by the 2D numerical simulation. Taken all the 2-D effects on front gate dielectric, back gate dielectric and silicon film into account, the data validity of electrical equivalent oxide thickness is investigated by this model, as shows that it is valid only when the gate dielectric constant is relatively small.     

Multiple-gate SOI MOSFETs: device design guidelines

This paper describes computer simulations of various SOI MOSFETs with double and triple-gate structures, as well as gate-all-around devices. The concept of a triple-gate device with sidewalls extending into the buried oxide (hereby called a "/spl Pi/-gate" or "Pi-gate" MOSFET) is introduced. The Pi-gate device is simple to manufacture and offers electrical characteristics similar to the much harder to fabricate gate-all-around MOSFET. To explore the optimum design space for four different gate structures, simulations were performed with four variable device parameters: gate length, channel width, doping concentration, and silicon film thickness. The efficiency of the different gate structures is shown to be dependent of these parameters. The simulation results indicate that the the Pi-gate device is a very promising candidate for future nanometer MOSFET applications.     

Mobility-field behavior of fully depleted SOI MOSFET's

This work reports measured effective mobility vs. effective vertical electric field and the accompanying experimental method of extraction for the fully depleted (FD) SOI MOSFET. The effective channel mobility vs. effective vertical electric field behavior was investigated as a function of the SOI film doping concentration, the SOI back-gate bias, and the SOI film thickness. The validity of using the approximation, Q_i=C_ox(V_GS-V_TH), for the inversion charge density in FD SOI is examined and experimentally confirmed     

Characterization of double gate MOSFETs fabricated by a simple method on a recrystallized silicon film

A simple process to fabricate double gate SOI MOSFET is proposed. The new device structure utilizes the bulk diffusion layer as the bottom gate. The active silicon film is formed by recrystallized amorphous silicon film using metal-induced-lateral-crystallization (MILC). While the active silicon film is not truly single crystal, the material and device characteristics show that the film is equivalent to single crystal SOI film with high defect density, like SOI wafers produced in early days. The fabricated double gate MOSFETs are characterized, which demonstrate excellent device characteristics with higher current drive and stronger immunity to short channel effects compared to the single gate devices.     

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.     

Suppression of short channel effects by full inversion in deep sub-micron gate SOI MOSFETs

Classical modeling of fully inverted SOI MOSFET (FI MOSFET) has been performed. In FI MOSFETs, the top Si layer is thinner than the thickness of the inversion layer at the conducting state and so the depleted region in the top Si layer is completely eliminated. It was found that the gate electric field induces carriers in the channel more effectively in FI MOSFET than in the fully depleted SOI MOSFETs (FD MOSFET), so that the short channel effects can be suppressed significantly.     

FinFET design considerations based on 3-D simulation and analytical modeling

Design considerations of the FinFET have been investigated by three-dimensional (3-D) simulation and analytical modeling in this paper. Short-channel effects (SCE) of the FinFET can be reasonably controlled by reducing either silicon fin height or fin thickness. Analytical solution of 3-D Laplace's equation is employed to establish the design equations for the subthreshold behavior in the fully depleted silicon fins. Based on the 3-D analytical electrostatic potential in the subthreshold region, the threshold voltage (V/sub th/) roll-off and the subthreshold swing (S) are estimated by considering the source barrier changes in the most leaky channel path. V/sub th/ roll-off is an exponential function of the ratio of effective channel length to drain potential decay length, which can then be expressed as a function of the fin thickness, the fin height and the gate oxide thickness. The drain-potential decay lengths of single-gate fully depleted SOI MOSFET (FDFET), double-gate MOSFET (DGFET), rectangular surrounding-gate MOSFET (SGFET), and FinFET are compared. The drain potential scaling length and V/sub th/ roll-off can be included into a universal relation for convenient comparison.