Investigation of the novel attributes of a single-halo double gate SOI MOSFET: 2D simulation study

The novel features of an asymmetric double gate single halo (DG-SH) doped SOI MOSFET are explored theoretically and compared with a conventional asymmetric DG SOI MOSFET. The two-dimensional numerical simulation studies demonstrate that the application of single halo to the double gate structure results in threshold voltage roll-up, reduced DIBL, high drain output resistance, kink free output characteristics and increase in the breakdown voltage when compared with a conventional DG structure. For the first time, we show that the presence of single halo on the source side results in a step function in the surface potential, which screens the source side of the structure from the drain voltage variations. This work illustrates the benefits of high performance DG-SH SOI MOS devices over conventional DG MOSFET and provides an incentive for further experimental exploration.     

Parasitic bipolar gain in fully depleted n-channel SOI MOSFET's

Fully depleted SOI MOSFET's include an inherent parasitic lateral bipolar structure with a floating base. We present here the first complete physically based explanation of the bipolar gain mechanism, and its dependence on bias and technological parameters. A simple, one-dimensional physical model, with no fitting parameters, is constructed, and is shown to agree well with simulations and measurements performed on a new type of SOI MOSFET structure. It is shown that parameters which affect the gain, such as SOI layer thickness, body doping concentration and gate and drain voltages, do so primarily by affecting the concentration of holes in the body region. Thus, current gain falls dramatically with increasing drain voltage due to the associated impact ionization driven increase in the hole concentration. Gummel plots of this parasitic bipolar indicate an apparent ideality factor of 0.5 for the hole current, due to the body hole concentration's dependence on drain voltage     

A new symmetrical double gate nanoscale MOSFET with asymmetrical side gates for electrically induced source/drain

In this paper, we present the unique features exhibited by a novel double gate MOSFET in which the front gate consists of two side gates as an extension of the source/drain. The asymmetrical side gates are used to induce extremely shallow source/drain regions on either side of the main gate. Using two-dimensional and two-carrier device simulation, we have investigated the improvement in device performance focusing on the threshold voltage roll-off, the drain induced barrier lowering, the subthreshold swing and the hot carrier effect. Based on our simulation results, we demonstrate that the proposed symmetrical double gate SOI MOSFET with asymmetrical side gates for the induced source/drain is far superior in terms of controlling the short-channel effects when compared to the conventional symmetrical double gate SOI MOSFET. We show that when the side gate length is equal to the main gate length, the device can be operated in an optimal condition in terms of threshold voltage roll-off and hot carrier effect. We further show that in the proposed structure the threshold voltage of the device is nearly independent of the side gate bias variation.     

An SOI voltage-controlled bipolar-MOS device

This paper describes a new operation mode of the SOI MOSFET. Connecting the floating substrate to the gate in a short-channel SOI MOSFET allows lateral bipolar current to be added to the MOS channel current and thereby enhances the current drive capability of the device. Part of the bipolar current emitted by the source terminal merges into the channel before reaching the drain, which renders the base width substantially shorter than the gate length. This novel operating mode of a short-channel SOI transistor is particularly attractive for high-speed operation, since the device is capable of both reduced voltage swing operation and high current drive, n-p-n and p-n-p devices, as well as complementary inverters have been successfully fabricated.     

Investigation of the source/drain asymmetric effects due to gate misalignment in planar double-gate MOSFETs

A planar double-gate SOI MOSFET (DG-SOI) with thin channel and thick source/drain (S/D) was successfully fabricated. Using both experimental data and simulation results, the S/D asymmetric effect induced by gate misalignment was studied. For a misaligned DG-SOI, there is gate nonoverlapped region on one side and extra gate overlapped region on the other side. The nonoverlapped region introduces extra series resistance and weakly controlled channel, while the extra overlapped region introduces additional overlap capacitance and gate leakage current. We compared two cases: bottom gate shift to source side (DG/spl I.bar/S) and bottom gate shift to drain side (DG/spl I.bar/D). At the same gate misalignment value, DG/spl I.bar/S resulted in a larger drain-induced barrier lowering effect and smaller overlap capacitance at drain side than DG/spl I.bar/D. Because of reduced drain-side capacitance, the speed of three-stage ring oscillator of DG/spl I.bar/S, with 20% gate misalignment length (L/sub mis/) over gate length (L/sub g/), or L/sub mis//L/sub g/=20%, was faster than that of two-gate aligned DG-SOI.     

基于MOSFET漏电流温度特性的室温红外探测器

基于MOSFET的漏电流温度特性，提出了一种可与CMOS工艺兼容的新型室温红外探测器。它采用在SOI衬底上实现的MOSFET作为探测红外灵敏元，在MOSFET的钝化层上制作可提高红外吸收率的光学谐振腔，并利用硅微机械加工技术将SOI的隐埋氧化层悬空，形成热绝缘微桥结构。MOSFET在担当探测红外辐射灵敏元的同时，又作为放大处理电路的一部分，简化了电路。分析表明，探测器的探测率可高达10^9-10^10cmHz^1/2W^-1.     

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.     

异质栅非对称Halo SOI MOSFET亚阈值电流模型

在沟道源端一侧引入高掺杂Halo结构的异质栅SOI MOSFET,可以有效降低亚阈值电流.通过求解二维泊松方程,为该器件建立了亚阈值条件下的表面势模型.利用常规漂移.扩散理论,在表面势模型的基础上,推导出新结构器件的亚阈值电流模型.为了求解简单,文中给出了一种分段近似方法,从而得到表面势的解析表达式.结果表明,所得到的表面势解析表达式和确切解的结果高度吻合.二维器件数值模拟器ISE验证了通过表面势解析表达式得到的亚阈值电流模型,在亚阈值区二者所得结果吻合得很好.     

A silicon/indium arsenide source structure to suppress the parasitic bipolar-induced breakdown effect in SOI MOSFETs

We introduce Silicon/indium arsenide (Si/InAs) source submicron-device structure in order to minimize the impact of floating body effect on both the drain breakdown voltage and single transistor latch in ultra thin SOI MOSFETs. The potential barrier of valence band between source and body reduces by applying the Indium Arsenide (InAs) layer at the source region. Therefore, we can improve the drain breakdown by suppressing the parasitic NPN bipolar device and the hole accumulation in the body. As confirmed by 2D simulation results, the proposed structure provides the excellent performance compared with a conventional SOI MOSFET thus improving the reliability of this structure in VLSI applications.     

A novel nanoscaled device concept: quasi-SOI MOSFET to eliminate the potential weaknesses of UTB SOI MOSFET

For the first time, a novel device concept of a quasi-silicon-on-insulator (SOI) MOSFET is proposed to eliminate the potential weaknesses of ultrathin body (UTB) SOI MOSFET for CMOS scaling toward the 35-nm gate length, and beyond. A scheme for fabrication of a quasi-SOI MOSFET is presented. The key characteristics of quasi-SOI are investigated by an extensive simulation study comparing them with UTB SOI MOSFET. The short-channel effects can be effectively suppressed by the insulator surrounding the source/drain regions, and the suppression capability can be even better than the UTB SOI MOSFET, due to the reduction of the electric flux in the buried layer. The self-heating effect, speed performance, and electronic characteristics of quasi-SOI MOSFET with the physical channel length of 35 nm are comprehensively studied. When compared to the UTB SOI MOSFET, the proposed device structure has better scaling capability. Finally, the design guideline and the optimal regions of quasi-SOI MOSFET are discussed.     

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.     

A time-dependent technique for carrier recombination and generation lifetime measurement in SOI MOSFET

A time-dependent technique is developed for carrier recombination–generation (R–G) lifetimes measurement in the silicon-on-insulator (SOI) metal-oxide-semiconductor field-effect transistor (MOSFET). One gate is kept in strong accumulation, and the other gate is kept in strong inversion. A ramp voltage is applied to the accumulated gate, and the drain current transients are monitored for both carrier R–G lifetimes extraction. The time-dependent technique shows an extensive applicability, and its credibility is proved by simulation.     

Simulation of a high performance MOSFET with a quantum wirestructure incorporating a periodically bent Si-SiO2 interface

A MOSFET using a serrated quantum wire structure that produces one-dimensional electron confinement shows excellent subthreshold characteristics and enhanced drive capability compared to a conventional MOSFET with a flat Si-SiO₂ interface. We studied the quantum wire structure with its periodically bent Si-SiO₂ interface using simulations. The potential in the convex regions of the silicon is 0.34 V higher than that in the concave ones when the bending angle is 90°, the bending period is 100 nm, substrate doping is 3.0×10 ¹⁷ cm^-3, and a gate voltage is 0.1 V. Because of this increase in potential in the convex regions, electrons are confined in a narrow width of 13 nm in the convex regions. This 1-D electron confinement effect by the bent Si-SiO₂ interface is clearly observed at low gate voltage and is reduced as the gate voltage becomes higher. Due to the confinement effect, drain current in the MOSFET with this quantum wire structure is 270 times higher than that of a MOSFET with a flat Si-SiO₂ interface at a gate voltage of 0.05 V. In addition, the short-channel effect is more effectively suppressed in this MOSFET than in a conventional MOSFET     

Investigation of the Electrical and Thermal Performance of SOI MOSFETs with Modified Channel Engineering

In this paper, we present a novel type of channel doping engineering, using a graded doping distribution, that improves the electrical and thermal performance of silicon-on-insulator (SOI) metal–oxide–semiconductor field effect transistors (MOSFETs), according to simulations that we have performed. The results obtained include a reduction in the self-heating effect, a reduction in leakage currents due to the suppression of short-channel effects (SCEs), and a reduction in hot-carrier degradation. We term the proposed structure a modified-channel-doping SOI (MCD-SOI) MOSFET. The main reason for the reduction in the self-heating effect is the use of a lower doping density near the drain region in comparison with conventional SOI MOSFETs with a uniform doping distribution. The most significant reason for the leakage current reduction in the MCD-SOI structure is the high potential barrier near the source region in the weak inversion state. The SCE factors, including the drain-induced barrier lowering, subthreshold swing, and threshold voltage roll-off, are improved. A highly reliable structure is achieved owing to the lower doping density near the drain region, which reduces the peak electric field and the electron temperature.     

Zero-temperature-coefficient biasing point of partially depletedSOI MOSFET's

Experimental and analytical results of the front gate bias (V_GS) and the drain current (I_DS) with the drain voltage (V_DS) of partially depleted (PD) SOI MOSFET at the Zero-Temperature-Coefficient (ZTC) point over a very wide temperature range (25-300°C) are presented. Two distinct ZTC points are identified, one in the linear region and the other is in the saturation region. Additionally, the analysis takes into consideration the body effects, and mobility degradation with applied front gate bias. The analysis results are in excellent agreement with the experimental results     

Modeling of drain current overshoot and recombination lifetimeextraction in floating-body submicron SOI MOSFETs

This work reports on a new general modeling of recombination-based mechanisms related to electrically floating-body partially-depleted (PD) SOI MOSFETs. The model describes drain current overshoots induced when turning on the transistor gate and suggests a novel extraction method for the recombination lifetime in the silicon film. We show that the recombination process associated with drain current overshoots in PD silicon-on-insulator (SOI) MOSFETs takes place mainly in the depletion region and not in the neutral region as in case of pulsed MOS capacitors. Associated with existing techniques for generation lifetime extraction, our model offers, for the first time, the possibility of complete and rapid characterization for both generation and recombination lifetime using drain current transients in floating-body SOI MOSFETs. The model is used in order to characterize submicron SOI devices, allowing a thorough investigation of technological parameters impact on floating-body-induced transient mechanisms     

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.     

A novel high-performance asymmetric hetero-doped S/D high-voltage MOSFET

A novel high-voltage MOSFET structure, using a simple yet effective concept of an asymmetric hetero-doped source/drain (S/D) is proposed. The asymmetric hetero-doped S/D reduces the on-state resistance of the transistor due to the high doping used for device drain drift, provides excellent ruggedness for parasitic NPN turned-on due to a minimized n/sup +/ source spacer, and also raises the device breakdown voltage due to charge compensation in the composite drain drift region. Therefore, the asymmetric hetero-doped S/D structure allows the high voltage MOSFET to have a high current handling capability with a small device size. This in turn causes the R (sp, on) to be low, leading to high performance for the power device when used in a power integrated circuit. Measured results show that a 24-V breakdown voltage new device with a low-cost two-layer metal (Al) back-end achieves very low R (sp, on) of 0.166 m/spl Omega//spl middot/cm/sup 2/. Furthermore, the new device with a 65-V high-side capability achieves good isolation performance even when switching S/D to -20 V and also gets a cutoff frequency of 13 GHz at a gate voltage of 5.5 V.     

The Localized-SOI MOSFET as a Candidate for Analog/RF Applications

In this paper, the characteristics of a localized-SOI (L-SOI) MOSFET are investigated for analog/RF applications. In the L-SOI device, the source/drain regions are quasi-surrounded by L-type oxide layers to reduce junction capacitance and avoid source/drain punchthrough, while the channel is directly connected with the substrate to alleviate the self-heating effect. Such structures can combine the advantages of both bulk and SOI MOSFETs and avoid their issues. Due to the unique structure of this novel device, the L-SOI MOSFET can exhibit excellent analog/RF behaviors. Higher g _m / I _ds ratio and intrinsic gain (g _m / g _ds)can be received compared with the conventional SOI structure, particularly at low gate bias. Higher and , which are due to higher g _m and reduced gate capacitance, can be observed in the L-SOI MOSFET. In addition, better noise performance can be achieved resulting from reduced lattice temperature and improved g _m . Thus, the L-SOI MOSFET can be considered as one of the potential candidates for analog/RF applications.