A DC model for asymmetric trapezoidal gate MOSFET's in stronginversion

Asymmetric trapezoidal gate (ATG) MOSFET is an innovative device having a structure of a relatively narrow drain-side width in order to reduce parasitic effects for enhancing device performance. In this paper, we develop a DC model for ATG MOSFET's. We use a charge-based approach to explore the asymmetric feature between source and drain of ATG MOSFET's, and obtain analytic formulae for threshold voltage, body effect, drain current, and channel length modulation effect in linear and saturation regions for both forward and reverse modes of operations. The model provides a physical analysis of the ATG structure, shows good agreement with measurement data, and is useful in circuit simulation with ATG devices     

Microwave-Rectification RFI Response in Field-Effect Transistors

This paper discusses the rectification of microwave energy in low-medium frequency feld-effect transistors (FET's) and develops a small-signal model for RHI noise analysis in low-frequency linear circuitry. The modeling procedure centers on a Taylor series expansion of the gate voltage-drain current characteristic which shows a small increase in drain current due to a nicrowave voltage at the gate. The increase in drain current is proportional to the variation in transconductance with gate voltage, and the square of the microwave voltage. Analysis of the microwave power in the transistor shows that critical parameters in determnination of the sensitivity are the gate capacitance and the real part ofthe device input impedance, which ultimately is limited by the parasitic resistance between the active channel and contacts.     

A review of DC extraction methods for MOSFET series resistance and mobility degradation model parameters

The performance of modern MOSFETs is limited by the presence of parasitic series resistances and mobility degradation. This article reviews and assesses 18 of the extraction methods currently used to determine the values of parasitic series resistances and mobility degradation from the measured drain current. The methods are separated in 3 groups: seven different methods that use the transfer characteristics of several devices having different mask channel lengths; five methods based on a single device with different drain and gate bias; six methods which account for the asymmetry between drain and source resistance.     

A new extraction algorithm for the metallurgical channel length ofconventional and LDD MOSFETs

A new extraction algorithm for the metallurgical channel length of conventional and LDD MOSFETs is presented, which is based on the well-known resistance method with a special technique to eliminate the uncertainty of the channel length and to reduce the influence of the parasitic source/drain resistance on threshold-voltage determination. In particular, the metallurgical channel length is determined from a wide range of gate-voltage-dependent effective channel lengths at an adequate gate overdrive. The 2-D numerical analysis clearly show that adequate gate overdrive is strongly dependent on the dopant concentration in the source/drain region. Therefore, an analytic equation is derived to determine the adequate gate overdrive for various source/drain and channel doping. It shows that higher and lower gate overdrives are needed to accurately determine the metallurgical channel length of conventional and LDD MOSFET devices, respectively. It is the first time that we can give a correct gate overdrive to extract L_met not only for conventional devices but also for LDD MOS devices. Besides, the parasitic source/drain resistance can also be extracted using our new extraction algorithm     

The effect of high fields on MOS device and circuit performance

A simple analytical model for the MOS device characteristics including the effect of high vertical and horizontal fields on channel carrier velocity is presented. Analytical expressions for the drain current, saturation drain voltage, and transconductance are developed. These expressions are used to examine the effect of scaling the channel length, the gate dielectric thickness, and the bias voltage on device characteristics. Experimental results from various geometry MOS devices are used to verify the trends predicted by the model. Using the physical understanding provided by the model, we examine the effect of device geometry scaling on circuit performance. We suggest that for gate capacitance-limited circuits one should reduce the channel length, and for parasitic capacitance-limited circuits one should reduce the gate dielectric thickness to improve circuit performance.     

A study of parasitic resistance effects in thin-channel polycrystalline silicon TFTs with tungsten-clad source/drain

With selectively-deposited tungsten film grown on source/drain regions, the parasitic source/drain resistance of thin-channel polycrystalline silicon (poly-Si) thin film transistors can be greatly reduced, leading to the improvement of device driving ability. After extracting the parasitic resistance from characteristics of devices with different channel length, the influences of parasitic resistance on device performances were discussed. A physically-based equation containing the parasitic resistance effects was derived to explain the behavior of linear transconductance under high gate voltage. Good agreements were found between calculated and measured data for both the thin-channel devices with or without tungsten-clad source/drain structure.     

Advantage of further scaling in gate dielectrics below 0.5 nm of equivalent oxide thickness with La2O3 gate dielectrics

N-type metal-oxide-semiconductor field-effect transistor (MOSFET) with an equivalent oxide thickness (EOT) of 0.37 nm has been demonstrated with La₂O₃ as a gate dielectric for the first time. Despite the existence of parasitic capacitances at gate electrode and inversion layer in the channel, a sufficient drain current increment in both linear and saturation regions have been observed, while scaling the gate oxide from 0.48 to 0.37 nm in EOT. Therefore, continuous scaling of EOT below 0.5 nm is still effective for further improvement in device performance.     

A re-examination of practical performance limits of scaled n-channel and ϱ-channel MOS devices for VLSI

The device performance of scaled n-channel and p-channel MOS devices is theoretically examined in detail down to 0.2 μm gate length including all of the major effects such as source/drain series resistance, mobility degradation due to both parallel and perpendicular fields, and inversion layer capacitance under three different power supply scenarios. From the degradation factor of triode gain and drain saturation current, the relative contribution of each parasitic effect on device performance degradation has been examined. Based on these calculations, some modifications to straight-forward scaling are considered.     

Extraction of the series resistance and the effective mobility in enhancement MOSFETs from weak to strong inversion using a single transistor

This work presents a new approach for the simultaneous determination of the effective channel mobility and the parasitic series resistance as a function of gate voltage in enhancement MOSFETs. The proposed method is applicable for short channel devices as well as long channel ones. It also takes into consideration the effect of interface traps and the dependence of the effective channel length on gate bias. The method is based on the measurement of the dynamic transconductance, gate-channel capacitance and the ohmic region drain current all on a single MOS transistors. The obtained results suggest a peak for the effective mobility versus gate voltage near threshold. The parasitic series resistance for short channel devices shows only slight dependence on the gate bias in the whole strong inversion region. On the contrary, for long channel devices, the series resistance significantly decreases with increasing gate voltage at the onset of strong inversion and then tends to level off as the device is pushed deeper in strong inversion.     

Device-Optimization Technique for Robust and Low-Power FinFET SRAM Design in NanoScale Era

In this paper, we propose a methodology to model and optimize FinFET devices for robust and low-power SRAMs. We propose to optimize the gate sidewall offset spacer thickness to simultaneously minimize leakage current and drain capacitance to on-current ratio in FinFET. With the source/drain extension doping controlled at the outer edges of the spacer, the thickness of the spacer determines the channel length. Optimization reduces the sensitivity of the device threshold voltage to the fluctuations in silicon thickness (by 32%) and gate length (by 73%). Our analysis shows that optimization of spacer thickness results in 65% reduction in SRAM cell leakage and improves cell read-failure probability (by 200 X) compared to conventional FinFET SRAM. Access time of an SRAM cell designed with optimized devices is comparable to conventional SRAM. We also compared the optimized-spacer-thickness SRAM cell with one designed using longer gate length and minimum-spacer-thickness transistors. The long-channel-device-based SRAM cell is marginally robust than optimized SRAM; however, increased gate-edge direct-tunneling leakage and parasitic capacitances degrade the power consumption and access time.     

Extraction of gate dependent source/drain resistance and effective channel length in MOS devices at 77 K

A new extraction technique for obtaining the parasitic source/drain resistance and the effective channel length of an MOS device at 77 K is presented. Unlike previous methods, both parameters are assumed to vary with the gate voltage. This results in positive and physically meaningful results at any temperature. Simulation results show that, in non-LDD devices, the source/drain resistance decreases and the effective channel length increases with gate bias, indicating that the gate dependence of both parameters is inherent to MOS devices.<>     

I—V characteristics of GaAs MESFET with nonuniform doping profile

A simple analytical model of a GaAs MESFET with non-uniform doping is proposed. The analysis shows that at gate voltages well above the threshold (0.2-0.4 V) for a typical device the current saturation is related to the velocity saturation (with a possibility of a stationary domain formation at drain-to-source voltages high enough). Closer to the threshold the saturation is due to the channel pinchoff. In both regimes the nonuniformity of the doping profile may be essential. Another factor taken into consideration is the source series resistance which includes the contact resistance and the resistance of the gate-to-source region of the device. The calculated dependences of the transconductance and drain current on the gate voltage are in good agreement with the experimental results obtained by Eden, Zucca, Long, and others [1].     

A two-dimensional analysis of indium phosphide junction field effect transistors with long and short channels

A two-dimensional analysis of indium phosphide junction field effect transistors with long and short gates is presented. The two devices are shown to have properties similar to those of gallium arsenide JFETs. The short gate device has a negative resistance region at low drain voltages which is absent in the long gate device. The negative resistance region is determined by the distribution of the drift velocity along the conducting channel, and the resulting distribution of the electron charge. A field dependent mobility is used, and its effect on current saturation is discussed. The electrostatic charge distribution and electric field distribution are calculated for both devices, and are shown in graphic form.     

A two-dimensional analysis of gallium arsenide junction field effect transistors with long and short channels

A two-dimensional analysis of gallium arsenide junction field effect transistors with long and short gates is presented. The short gate device is shown to have a negative resistance region at low drain voltages which is absent in the long gate device. The negative resistance region depends on the shape of the conducting channel and the distribution of the electron charge. A field dependent mobility is used, and its effect on current saturation is discussed. The electrostatic charge distribution and electric field distribution are calculated for both devices, and are shown in graphic form.     

TiA1和TiPtAu栅GaAs MESFET稳定性研究

在高温和大栅电流下 ,对 Ti Al栅和 Ti Pt Au栅 MESFET的稳定性进行了比较研究 ,结果表明 :( 1)两种器件的击穿电压稳定 ,栅 Schottky接触二极管理想因子 n变化不明显 ;( 2 ) Ti Al栅的 MESFET的栅特性参数 (栅电阻 Rg,势垒高度 Φb)变化明显 ,与沟道特性相关的器件参数 (如最大饱和漏电流 Idss,栅下沟道开路电阻 R0 ,夹断电压 Vp0 等 )保持相对不变 ;( 3)对 Ti Pt Au栅MESFET来说 ,栅 Schottky二极管特性 (栅电阻 Rg,势垒高度 Φb)保持相对稳定 ,与沟道特性相关的器件参数 (如最大饱和漏电流 Idss,栅下沟道开路电阻 R0 ,夹断电压 Vp0 、跨导 gm 等 )明显变化 ,适当退火后 ,有稳定的趋势。这两种器件的参数变化形成了鲜明的对比。     

Modeling of parasitic capacitances in deep submicrometer conventional and high-K dielectric MOS transistors

In deep submicrometer MOSFETs the device performance is limited by the parasitic capacitance and resistance. Hence a circuit model is needed to treat these effects correctly. In this work, we have developed circuit models for the parasitic capacitances in conventional and high-K gate dielectric MOS transistors by taking into account the presence of source/drain contact plugs. The accuracy of the model is tested by comparing the modeled results with the results obtained from three-dimensional (3-D) Monte-Carlo simulations and two-dimensional (2-D) device simulations over a wide range of channel length and oxide thickness. The model is also used to study the dependence of parasitic capacitance on gate length, gate electrode thickness, gate oxide thickness, gate dielectric constant, and spacer width.     

热载流子应力下n-MOSFET线性漏电流的退化

研究了不同沟道和栅氧化层厚度的n-M O S器件在衬底正偏压的VG=VD/2热载流子应力下,由于衬底正偏压的不同对器件线性漏电流退化的影响。实验发现衬底正偏压对沟长0.135μm,栅氧化层厚度2.5 nm器件的线性漏电流退化的影响比沟长0.25μm,栅氧化层厚度5 nm器件更强。分析结果表明,随着器件沟长继续缩短和栅氧化层减薄,由于衬底正偏置导致的阈值电压减小、增强的寄生NPN晶体管效应、沟道热电子与碰撞电离空穴复合所产生的高能光子以及热电子直接隧穿超薄栅氧化层产生的高能光子可能打断S i-S iO2界面的弱键产生界面陷阱,加速n-M O S器件线性漏电流的退化。     

A one-dimensional theory on the effects of diffusion current and carrier velocity saturation on E-type IGFET current-voltage characteristics

Current-voltage characteristics of an enhancement-type insulated gate field-effect transistor (E-type IGFET) are analyzed based on a one-dimensional model, taking account also of the diffusion current component. Explicit formulae for the entire I-V characteristic curve are given. The solution for the triode characteristic shows considerable deviation from “drift current theory” in terms of turn-on voltage (or threshold voltage) and drain voltage at just saturation. The solution for the pentode characteristic taking account of carrier's saturation velocity, shows that the increase in drain current per unit drain voltage is larger in short-channel devices than in long-channel devices. Agreement with experiment is very good.     

6H-SiC MOS场效应晶体管的研制

报道了多晶硅栅 6 H- Si C MOS场效应器件的制造工艺和器件性能。 6 H- Si C氧化层的SIMS分析说明在氧化过程中 ,多余的 C以 CO的形式释放 ,铝元素逸出极少 ,氧化层中因有较多的铝而正电荷密度较大 ,Si C的氧化速率和掺杂类型关系不大。器件漏电流都有很好的饱和特性 ,最大跨导为 0 .36 m S/ mm ,沟道电子迁移率约为 14cm2 / V.s,但串联电阻效应明显。