Design and simulation of nanoscale double-gate TFET/tunnel CNTFET

A double-gate tunnel field-effect transistor (DG tunnel FET) has been designed and investigated for various channel materials such as silicon (Si),gallium arsenide (GaAs),alminium gallium arsenide (AlxGa1xAs) and CNT using a nano ViDES Device and TCAD SILVACO ATLAS simulator.The proposed devices are compared on the basis of inverse subthreshold slope (SS),ION/IoFF current ratio and leakage current.Using Si as the channel material limits the property to reduce leakage current with scaling of channel,whereas the AlxGalxAs based DG tunnel FET provides a better ION/IoFF current ratio (2.51 × 106) as compared to other devices keeping the leakage current within permissible limits.The performed silmulation of the CNT based channel in the double-gate tunnel field-effect transistor using the nano ViDES shows better performace for a sub-threshold slope of 29.4 mV/dec as the channel is scaled down.The proposed work shows the potential of the CNT channel based DG tunnel FET as a futuristic device for better switching and high retention time,which makes it suitable for memory based circuits.     

Analysis and impact of process variability on performance of junctionless double gate VeSFET

This paper presents an in-depth analysis of junctionless double gate vertical slit FET (JLDG VeSFET) device under process variability. It has been observed that junctionless FETs (JLDG VeSFET) are significantly less sensitive to many process parameter variations due to their inherent device structure and geometric properties. Sensitivity analysis reveals that the slit width, oxide thickness, radius of the device, gate length and channel doping concentration imperceptibly affect the device performance of JLDG VeSFET in terms of variation in threshold voltage, on current, off current and subthreshold slope (Ssub) as compared to its junction based counterpart i.e. MOSFET, because various short channel effects are well controlled in this device. The maximum variation in off current for JLDG VeSFET due to variation in different devices parameters is 5.6% whereas this variation is 38.8% for the MOS junction based device. However, variation in doping concentration in the channel region displays a small deviation in the threshold voltage and on current characteristics of the MOSFET device as compared to JL DG VeSFET.     

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.     

Analytical modeling of subthreshold current and subthreshold swing of an underlap DGMOSFET with tied-independent gate and symmetric-asymmetric options

Novel analytical models for subthreshold current and subthreshold slope of a generic underlap DGMOSFET are proposed. The proposed models are validated with published models, experimental data along with numerical simulation results. The reasonably good agreement shows the accuracy of the proposed model. It is demonstrated how device subthreshold leakage current and subthreshold slope values can be favorably affected by proper back gate biasing, back gate asymmetry and gate work function engineering in combination with gate underlap engineering. It is demonstrated that independent gate operation in combination with gate underlap engineering significantly reduce subthreshold leakage currents as compared to nonunderlap-tied gate DGMOSFET. With the reduction in body thickness, an improvement in subthreshold slope value of underlap 4T DGMOSFET is seen, particularly as back/front gate oxide asymmetry. Developed models demonstrate that asymmetric work function underlap 4T DGMOSFETs would have better device subthreshold slope value along with increased back gate oxide asymmetry.     

Nanoscale Ⅲ-Ⅴ on Si-based junctionless tunnel transistor for EHF band applications

A single gate Ⅲ-Ⅴ junctionless tunnel field effect transistor (SG-JLTFET) has been reported which shows excellent dc characteristics at low power supply operation.This device has a thin uniformly n-type doped channel of GaSb i.e.gallium antimonide which is grown epitaxially over silicon substrate.The DC performance parameters such as ION,ION/IOFF,average and point subthreshold slope as well as device parameters for analog applications viz.transconductance gm,transconductance generation efficiency gm/ID,various capacitances and the unity gain frequency fT are studied using a device simulator.Along with examining its endurance to short channel effects,the performances are also compared with a Silicon Dual Gate Junctionless Tunnel FET (DG-JLTFET).The DC and small signal analog performance reflects that GaSb SG-JLTFET has immense purview for extreme high-frequency and low-power applications.     

Effect of Gate Leakage in the Subthreshold Characteristics of AlGaN/GaN HEMTs

This letter studies the effect of gate leakage on the subthreshold slope and ON/OFF current ratio of AlGaN/GaN high-electron mobility transistors (HEMTs). We found a strong correlation between the gate leakage current and the transistor subthreshold characteristics: the lower the gate leakage, the higher the ON/OFF ratio and the steeper the subthreshold slope. To improve the subthreshold characteristics in GaN HEMTs, the gate leakage current was reduced with an $hbox{O}_{2}$ plasma treatment prior to the gate metallization. The $hbox{O}_{2}$ plasma treatment effectively reduces the gate leakage current by more than four orders of magnitude, it increases the ON/OFF ratio to more than seven orders of magnitude and the improved AlGaN/GaN HEMT shows a nearly ideal subthreshold slope of 64 mV/dec.      

Hetero-gate-dielectric double gate junctionless transistor (HGJLT) with reduced band-to-band tunnelling effects in subthreshold regime

We propose a hetero-gate-dielectric double gate junctionless transistor （HGJLT）, taking high-k gate insulator at source side and low-k gate insulator at drain side, which reduces the effects ＆band-to-band tunnelling （BTBT） in the sub-threshold region. A junctionless transistor （JLT） is turned off by the depletion of carriers in the highly doped thin channel （device layer） which results in a significant band overlap between the valence band of the channel region and the conduction band of the drain region, due to off-state drain bias, that triggers electrons to tunnel from the valence band of the channel region to the conduction band of the drain region leaving behind holes in the channel.These effects of band-to-band tunnelling increase the sub-threshold leakage current, and the accumulation of holes in the channel forms a parasitic bipolar junction transistor （n-p-n BJT for channel JLT） in the lateral direction by the source （emitter）, channel （base） and drain （collector） regions in JLT structure in off-state. The proposed HGJLT reduces the subthreshold leakage current and suppresses the parasitic BJT action in off-state by reducing the band-to-band tunnelling probability.     

沟道形状对无结型多栅器件性能影响探究

随着集成电路特征尺寸进入纳米尺度,摩尔定律的延续受到一定的挑战,纳米技术代的晶体管亟需全新的材料、器件结构和工艺集成技术。在器件结构方面,无结型场效应晶体管由于其近似理想的电流电压特性、优良的等比例缩小能力以及极其简单的制造工艺,受到了人们广泛的关注。通过三维数值仿真工具Synopsys Sentaurus 3DTCAD,对多栅的无结型MOS晶体管进行了数值模拟仿真。并在此基础上探究了无结型器件沟道形状对其电学特性的影响,提出了具有倒角正梯形沟道的多栅无结型晶体管结构,验证了其相较于普通无结多栅型器件更加优良的电学特性,以及栅长下降至20nm以下节点时对短沟道效应的进一步抑制作用。     

双栅无结型场效应晶体管的设计与优化

利用三维数值仿真工具,对双栅无结型场效应晶体管进行了数值模拟,研究了沟道掺杂浓度深度分布对晶体管性能的影响,并对比分析了当沟道长度缩小到10nm及以下时器件的电学特性。仿真结果表明,相比于沟道为均匀掺杂分布的器件,具有中间低的沟道掺杂深度分布的双栅无结型场效应晶体管具有更优的开关电流比、漏致势垒降低、亚阈值斜率等电学性能和短沟道特性。     

Subthreshold behavior models for short-channel junctionless tri-material cylindrical surrounding-gate MOSFET

A novel junctionless tri-material cylindrical surrounding-gate (JLTMCSG) MOSFET is presented in this paper. The subthreshold behavior of JLTMCSG MOSFET is investigated by developing physical based analytical models for channel electrostatic potential, horizontal electric field, and subthreshold current. It is revealed that JLTMCSG MOSFET can effectively suppress DIBL and simultaneously improve carrier transport efficiency. It is also found that subthreshold current for JLTMCSG MOSFET can be significantly reduced by adopting both a small oxide thickness and a thin silicon channel. The accuracy of analytical model is verified by its good agreement with the three-dimensional numerical device simulator ISE.     

Subthreshold design considerations for insulated gate field-effect transistors

A knowledge of subthreshold behavior in an insulated gate field-effect transistor is important for circuits with low leakage specifications. This paper discusses the effect of drain voltage on the subthreshold region as the channel length becomes shorter, the effect of substrate bias on both the shift in and the slope of the subthreshold curves, and the effect of temperature on the subthreshold current characteristics. It is shown that all these effects can be incorporated into a simple one-dimensional model.     

Performance enhancement of offset gated polysilicon thin-film transistors

Simple offset gated n-channel polysilicon thin film transistors (TFTs) of channel length L=10 /spl mu/m were investigated in relation to the intrinsic offset length /spl Delta/L and the polysilicon quality. For /spl Delta/L/spl les/1 /spl mu/m, the device parameters such as threshold voltage, subthreshold slope and field effect mobility are improved, while the leakage current remains unchanged. In TFTs with /spl Delta/L>1 /spl mu/m, the leakage current decreases with increasing the offset length. When the polysilicon layer is of high quality (large grain size and low intra-grain defect density), the leakage current is completely suppressed without sacrificing the on-current in TFT's with offset length of 2 /spl mu/m.     

The Impact of Deep Ni Salicidation and$hboxNH_3$Plasma Treatment on Nano-SOI FinFETs

In this letter, 50-nm gate-length nano-silicon-on-insulator FinFETs with deep Ni salicidation and$hboxNH_3$plasma treatment are fabricated. It is found that device performances, including subthreshold slope (SS) drain-induced barrier lowering (DIBL) and off-state leakage current, can be greatly improved by using deep Ni salicidation process compared to no Ni salicidation process. The deep Ni-salicided devices effectively suppress the floating-body effect and parasitic bipolar junction transistor action. In addition, the effect of$hboxNH_3$plasma on the deep Ni-salicided devices is discussed. Experimental results reveal that the devices under a new state-of-the-art$hboxNH_3$plasma process can achieve better performance such as an SS of 66 mV/dec and a DIBL of 0.03 V.     

P-type double gate junctionless tunnel field effect transistor

We have investigated the 20 nm p-type double gate junctionless tunnel field effect transistor （P-DGJLTFET） and the impact of variation of different device parameters on the performance parameters of the P-DGJLTFET is discussed. We achieved excellent results of different performance parameters by taking the optimized device parameters of the P-DGJLTFET. Together with a high-k dielectric material （TiO2） of 20 nm gate length, the simulation results of the P-DGJLTFET show excellent characteristics with a high IoN of ～ 0.3 mA/μm, a low/OFF of ～ 30 fA/μm, a high ION/IOFF ratio of ～ 1×10^10, a subthreshold slope （SS） point of ～ 23 mV/decade, and an average SS of ～ 49 mV/decade at a supply voltage of -1 V and at room temperature, which indicates that PDGJLTFET is a promising candidate for sub-22 nm technology nodes in the implementation of integrated circuits.     

Double gate-MOSFET subthreshold circuit for ultralow power applications

In this paper, we propose MOSFETs that are suitable for subthreshold digital circuit operations. The MOSFET subthreshold circuit would use subthreshold leakage current as the operating current to achieve ultralow power consumption when speed is not of utmost importance. We derive the theoretical limit of delay and energy consumption in MOSFET subthreshold circuit, and show that devices that have an ideal subthreshold slope are optimal for subthreshold operations due to the smaller gate capacitance, as well as the higher current. The analysis suggests that a double gate (DG)-MOSFET is promising for subthreshold operations due to its near-ideal subthreshold slope. The results of our investigation into the optimal device characteristics for DG-MOSFET subthreshold operation show that devices with longer channel length (compared to minimum gate length) can be used for robust subthreshold operation without any loss of performance. In addition, it is shown that the source and drain structure of DG-MOSFET can be simplified for subthreshold operations since source and drain need not be raised to reduce the parasitic resistance.     

Modeling the subthreshold swing in MOSFET's

This letter reports on the bias-dependence of the inverse subthreshold slope or subthreshold swing in MOSFET's. It is shown by calculations and verified by experiments that the subthreshold swing varies with gate bias and exhibits a global minimum. The gate-source voltage for which minimum subthreshold swing is reached, is linearly related to the voltage at which moderate inversion starts. Influence of oxide thickness and temperature is investigated. The subthreshold swing is an important parameter in modeling the weak inversion regime, especially for high-gain analog applications, imaging circuits, and low-voltage applications. Based on calculations of the subthreshold swing, we propose a new model for the diffusion component of the drain leakage current in MOSFET's. The model accurately predicts the temperature dependence of the drain leakage current     

Enhanced I ON/I OFF in ultra deep submicron CMOS devices using grooved nMOSFETs in comparison to planar nMOSFET

To manage the increasing static leakage in low power applications and reducing ON‐OFF current ratio due to scaling limitations, solutions for leakage reduction as well as improving the current drive of the device are sought at the device design and process technology levels. At the device design level, the important low power variables are the threshold voltage, the gate leakage current, the subthreshold leakage current and the device size. Grooved‐gate MOS devices are considered as the most promising candidates for use in submicron and deep submicron regions as they can overcome the short‐channel effects effectively. By varying the corner angle and adjusting other structural parameters such as junction depth, channel doping concentration, negative junction depth and oxide thickness, leakage current in nMOS devices can be minimised. In this article, 90, 80, 70, 60 and 50?nm devices are simulated using Devedit and Deckbuild module of Silvaco device simulator. The simulated results show that by changing the structural parameters, ON‐OFF current ratio is improved and maintained constant even in the deep submicron region. This study can be helpful for low power applications as the static leakage is drastically reduced, as well as applicable to high speed devices as the ON current is maintained at a constant value. The results are compared with those of corresponding conventional planar devices to bring out the achievements of this study.     

Leakage Current Reduction Using Subthreshold Source-Coupled Logic

The performance of subthreshold source-coupled logic (STSCL) circuits for ultra-low-power applications is explored. It is shown that the power consumption of STSCL circuits can be reduced well below the subthreshold leakage current of static CMOS circuits. STSCL circuits exhibit a better power–delay performance compared with their static CMOS counterparts in situations where the leakage current constitutes a significant part of the power dissipation of static CMOS gates. The superior control on power consumption, in addition to the lower sensitivity to the process and supply voltage variations, makes the STSCL topology very suitable for implementing ultra-low-power low-frequency digital systems in modern nanometer-scale technologies. An analytical approach for comparing the power–delay performance of these two topologies is proposed.      

DC performance of deep submicrometer Schottky-gated n-channel Si:SiGe HFETs at low temperatures

N-type Schottky-gated Si:SiGe heterostructure field-effect transistors with physical gate lengths between 70 and 450nm are characterized over a wide temperature range (T=10 K...300 K) for low electric fields. The room-temperature maximum low-field transconductance increases 61% to 440 mS/mm at T=10 K for the 70-nm device. The minimum subthreshold slope is 14...19 mV/dec at T=10 K. The off-state currents I/sub OFF/ are limited by parallel conduction at high temperatures and by the gate leakage current at low temperatures. Substrate leakage currents are found to be due to generation of carriers within the drain/substrate depletion layer and only make a minor contribution to I/sub OFF/. Operation of the devices at the lowest temperature is found to result in the occurrence of the floating-body kink effect, as a consequence of substrate freeze-out and subsequent self-biasing by impact ionization currents. Low temperature characteristics exhibit a nonlinear low-field drain current dependence on the drain voltage, due to the presence of parasitic Schottky source/drain contacts. An extraction method for access resistance consistent with this phenomenon is presented.     

Transient Performance Estimation of Charge Plasma Based Negative Capacitance Junctionless Tunnel FET

We investigate the transient behavior of an n-type double gate negative capacitance junctionless tunnel field effect transistor (NC-JLTFET). The structure is realized by using the work-function engineering of metal electrodes over a heavily doped n⁺ silicon channel and a ferroelectric gate stack to get negative capacitance behavior. The positive feedback in the electric dipoles of ferroelectric materials results in applied gate bias boosting. Various device transient parameters viz. transconductance, output resistance, output conductance, intrinsic gain, intrinsic gate delay, transconductance generation factor and unity gain frequency are analyzed using ac analysis of the device. To study the impact of the work-function variation of control and source gate on device performance, sensitivity analysis of the device has been carried out by varying these parameters. Simulation study reveals that it preserves inherent advantages of charge-plasma junctionless structure and exhibits improved transient behavior as well.