Uncoupled mode space approach for analysis of nanoscale strained junctionless double-gate MOSFET

In this paper, we have analyzed the electrical characteristics of Strained Junctionless Double-Gate MOSFET (Strained JL DG MOSFET). A quantum mechanical transport approach based on non-equilibrium Green’s function (NEGF) method with the use of uncoupled mode space approach has been employed for this analysis. We have investigated the effects of high-\(\kappa \) materials as gate and spacer dielectrics on the device performance. Low OFF-state current, low DIBL, and low subthreshold slope have been obtained with increase in the gate and spacer dielectric constants. The electrical characteristics of strained JL DG MOSFET have also been compared with conventional JL DG MOSFET and Inversion Mode (IM) DG MOSFET. The results indicated that the Strained JL DG MOSFET outperforms the conventional JL and IM DG MOSFETs, yielding higher values of drain current.     

An analytical model of triple‐material double‐gate metal–oxide–semiconductor field‐effect transistor to suppress short‐channel effects

This paper presents an analytical subthreshold model for surface potential and threshold voltage of a triple‐material double‐gate (DG) metal–oxide–semiconductor field‐effect transistor. The model is developed by using a rectangular Gaussian box in the channel depletion region with the required boundary conditions at the source and drain end. The model is used to study the effect of triple‐material gate structure on the electrical performance of the device in terms of changes in potential and electric field. The device immunity against short‐channel effects is evaluated by comparing the relative performance parameters such as drain‐induced barrier lowering, threshold voltage roll‐off, and subthreshold swing with its counterparts in the single‐material DG and double‐material DG metal–oxide–semiconductor field‐effect transistors. The developed surface potential model not only provides device physics insight but is also computationally efficient because of its simple compact form that can be utilized to study and characterize the gate‐engineered devices. Furthermore, the effects of quantum confinement are analyzed with the development of a quantum‐mechanical correction term for threshold voltage. The results obtained from the model are in close agreement with the data extracted from numerical Technology Computer Aided Design device simulation. Copyright © 2015 John Wiley & Sons, Ltd.     

Investigation of multi‐layered‐gate electrode workfunction engineered recessed channel (MLGEWE‐RC) sub‐50 nm MOSFET: A novel design

In this paper, a two‐dimensional (2D) analytical sub‐threshold model for a novel sub‐50 nm multi‐layered‐gate electrode workfunction engineered recessed channel (MLGEWE‐RC) MOSFET is presented and investigated using ATLAS device simulator to counteract the large gate leakage current and increased standby power consumption that arise due to continued scaling of SiO₂‐based gate dielectrics. The model includes the evaluation of surface potential, electric field along the channel, threshold voltage, drain‐induced barrier lowering, sub‐threshold drain current and sub‐threshold swing. Results reveal that MLGEWE‐RC MOSFET design exhibits significant enhancement in terms of improved hot carrier effect immunity, carrier transport efficiency and reduced short channel effects proving its efficacy for high‐speed integration circuits and analog design. Copyright © 2008 John Wiley & Sons, Ltd.     

Two-dimensional analytical model of threshold voltage and drain current of a double-halo gate-stacked triple-material double-gate MOSFET

We have developed a two-dimensional analytical model for the channel potential, threshold voltage, and drain-to-source current of a symmetric double-halo gate-stacked triple-material double-gate metal–oxide–semiconductor field-effect transistor (MOSFET). The two-dimensional Poisson’s equation is solved to obtain the channel potential. For accurate modeling of the device, fringing capacitance and effective surface charge are considered. The basic drift–diffusion equation is used to model the drain-to-source current. The midchannel potential of the device is used instead of the surface potential in the current modeling, considering the fact that the punch-through current is not confined only to the surface in a fully depleted MOSFET. An expression for the pinch-off voltage is derived to model the drain current in the saturation region accurately. Various short-channel effects such as drain-induced barrier lowering, gate leakage, threshold voltage, and roll-off have also been investigated. This structure shows excellent ability to suppress various short-channel effects. The results of the proposed model are validated against data obtained from a commercially available numerical device simulator.     

Monte Carlo analysis of dynamic characteristics and high‐frequency noise performances of nanoscale double‐gate MOSFETs

In this paper, a full‐band Monte Carlo simulator is employed to study the dynamic characteristics and high‐frequency noise performances of a double‐gate (DG) metal–oxide–semiconductor field‐effect transistor (MOSFET) with 30 nm gate length. Admittance parameters (Y parameters) are calculated to characterize the dynamic response of the device. The noise behaviors of the simulated structure are studied on the basis of the spectral densities of the instantaneous current fluctuations at the drain and gate terminals, together with their cross‐correlation. Then the normalized noise parameters (P, R, and C), minimum noise figure (NF_min), and so on are employed to evaluate the noise performances. To show the outstanding radio‐frequency performances of the DG MOSFET, a single‐gate silicon‐on‐insulator MOSFET with the same gate length is also studied for comparison. The results show that the DG structure provides better dynamic characteristics and superior high‐frequency noise performances, owing to its inherent short‐channel effect immunity, better gate control ability, and lower channel noise. Copyright © 2012 John Wiley & Sons, Ltd.     

MOSFET开关过程的研究及米勒平台振荡的抑制

设计功率MOSFET驱动电路时需重点考虑寄生参数对电路的影响。米勒电容作为MOSFET器件的一项重要参数,在驱动电路的设计时需要重点关注。重点观察了MOSFET的开通和关断过程中栅极电压、漏源极电压和漏源极电流的变化过程,并分析了米勒电容、寄生电感等寄生参数对漏源极电压和漏源极电流的影响。分析了栅极电压在米勒平台附近产生振荡的原因,并提出了抑制措施,对功率MOSFET的驱动设计具有一定的指导意义。     

Asymmetric halo and symmetric Single‐Halo Dual‐Material Gate and Double‐Halo Dual‐Material Gate n‐MOSFETs characteristic parameter modeling

This paper presents an analytical subthreshold surface potential model of novel structures called asymmetric pocket‐implanted Double‐Halo Dual‐Material Gate (DHDMG) and Single‐Halo Dual‐Material Gate (SHDMG) Metal Oxide Semiconductor Field Effect Transistor (MOSFET), which combines the advantages of both the channel engineering (halo) and the gate engineering techniques (dual‐material gate) to effectively suppress the short‐channel effects (SCEs). The model is derived using the pseudo‐2D analysis by applying the Gauss's law to an elementary rectangular box in the channel depletion region, considering the surface potential variation with the channel depletion layer depth. The asymmetric pocket‐implanted model takes into account the effective doping concentration of the two linear pocket profiles at the source and the drain ends. The inner fringing field capacitances are also considered in the model for accurate estimation of the subthreshold surface potential at the two ends of the MOSFET. The same model is used to find the characteristic parameters for dual‐material gate with single‐halo and double‐halo implantations. It is concluded that the DHDMG device structure exhibits better suppression of the SCEs and the threshold voltage roll‐off than a pocket‐implanted and SHDMG MOSFET after investigating the characteristics parameter improvement. In order to validate our model, the modeled expressions have been extensively compared with the simulated characteristics obtained from the 2D device simulator DESSIS. A nice agreement is achieved with a reasonable accuracy over a wide range of device parameter and bias condition. Copyright © 2012 John Wiley & Sons, Ltd.     

Impact of channel length,gate insulator thickness,gate insulator material,and temperature on the performance of nanoscale FETs

Aggressive technology scaling as per Moore’s law has led to elevated power dissipation levels owing to an exponential increase in subthreshold leakage power. Short channel effects (SCEs) due to channel length reduction, gate insulator thickness change, application of high-k gate insulator, and temperature change in a double-gate metal–oxide–semiconductor field-effect transistor (DG MOSFET) and carbon nanotube field-effect transistor (CNTFET) were investigated in this work. Computational simulations were performed to investigate SCEs, viz. the threshold voltage (V_th) roll-off, subthreshold swing (SS), and I_on/I_off ratio, in the DG MOSFET and CNTFET while reducing the channel length. The CNTFET showed better performance than the DG MOSFET, including near-zero SCEs due to its pure ballistic transport mechanism. We also examined the threshold voltage (V_th), subthreshold swing (SS), and I_on/I_off ratio of the DG MOSFET and CNTFET with varying gate insulator thickness, gate insulator material, and temperature. Finally, we handpicked almost similar parameters for both the CNTFET and DG MOSFET and carried out performance analysis based on the simulation results. Comparative analysis of the results showed that the CNTFET provides 47.8 times more I_on/I_off ratio than the DG MOSFET. Its better control over the threshold voltage, near-zero SCEs, high on-current, low leakage power consumption, and ability to operate at high temperature make the CNTFET a viable option for use in enhanced switching applications and low-voltage digital applications in nanoelectronics.     

1/f Noise: threshold voltage and ON-current fluctuations in 45 nm device technology due to charged random traps

Discrete impurity effects in terms of their statistical variations in number and position in the inversion and depletion region of a MOSFET, as the gate length is aggressively scaled, have recently been investigated as being a major cause of reliability degradation observed in intra-die and die-to-die threshold voltage variation on the same chip resulting in significant variation in saturation drive (on) current and transconductance degradation—two key metrics for benchmark performance of digital and analog integrated circuits. In this paper, in addition to random dopant fluctuations (RDF), the influence of random number and position of interface traps lying close to Si/SiO₂ interface has been examined as it poses additional concerns because it leads to enhanced experimentally observed fluctuations in drain current and threshold voltage. In this context, the authors of this article present novel EMC based simulation study on trap induced random telegraph noise (RTN) responsible for statistical fluctuation pattern observed in threshold voltage, its standard deviation and drive current in saturation for 45 nm gate length technology node MOSFET device. From the observed simulation results and their analysis, it can be projected that with continued scaling in gate length and width, RTN effect will eventually supersede as a major reliability bottleneck over the already present RDF phenomenon. The fluctuation patterns observed by EMC simulation outcomes for both drain current and threshold voltage have been analyzed for the cases of single trap and two traps closely adjacent to one another lying in the proximity of the Si/SiO₂ interface between source to drain region of the MOSFET and explained from analytical device physics perspectives.     

Potential‐based threshold voltage and subthreshold swing models for junctionless double‐gate metal‐oxide‐semiconductor field‐effect transistor with dual‐material gate

On the basis of quasi‐two‐dimensional solution of Poisson's equation, an analytical threshold voltage model for junctionless dual‐material double‐gate (JLDMDG) metal‐oxide‐semiconductor field‐effect transistor (MOSFET) is developed for the first time. The advantages of JLDMDG MOSFET are proved by comparing the central electrostatic potential and electric field distribution with those of junctionless single‐material double‐gate (JLSMDG) MOSFET. The proposed model explicitly shows how the device parameters (such as the silicon thickness, oxide thickness, and doping concentration) affect the threshold voltage. In addition, the variations of threshold voltage roll‐off, drain‐induced barrier lowering (DIBL), and subthreshold swing with the channel length are investigated. It is proved that the device performance for JLDMDG MOSFET can be changed flexibly by adjusting the length ratios of control gate and screen gate. The model is verified by comparing its calculated results with those obtained from three‐dimensional numerical device simulator ISE. Copyright © 2015 John Wiley & Sons, Ltd.     

Continuity equation based nonquasi-static charge model for independent double gate MOSFET

Using the numerical device simulation we show that the relationship between the surface potentials along the channel in any double gate (DG) MOSFET remains invariant in QS (quasistatic) and NQS (nonquasi-static) condition for the same terminal voltages. This concept along with the recently proposed ‘piecewise charge linearization’ technique is then used to develop the intrinsic NQS charge model for a Independent DG (IDG) MOSFET by solving the governing continuity equation. It is also demonstrated that unlike the usual MOSFET transcapacitances, the inter-gate transcapacitance of a IDG-MOSFET initially increases with the frequency and then saturates, which might find novel analog circuit application. The proposed NQS model shows good agreement with numerical device simulations and appears to be useful for efficient circuit simulation.     

Study of RF Linearity in sub-50 nm MOSFETs Using Simulations

We investigate the linearity performance of dual-gate and fully-depleted silicon-on-insulator MOSFETs through use of 2D computer simulations, which take into account quantum mechanical considerations and non-equilibrium transport effects. We show that DG MOSFET is superior not only in terms of g _m /I _d characteristics, central to analog performance, but also in terms of linearity performance, by up to 5 dBm, in most operating conditions. Linearity figures of devices considered in this work range from ?10 to ?20 dBm, which answer the needs of mobile communication standards currently in use. We also observe that, when properly scaled, bulk MOSFETs display competitive analog performance and have third-order intercept figures very similar to SOI device. We can identify, through simulation experiments, that quantum mechanical effects have positive impact on linearity, while non-equilibrium conditions lower linearity performance. With increasing drain bias, we find that linearity saturates at a moderately low voltage (～1 V) in all devices.     

Explicit modelling of the double‐gate MOSFET with VHDL‐AMS

This paper presents a new compact model for the undoped, long‐channel double‐gate (DG) MOSFET under symmetrical operation. In particular, we propose a robust algorithm for computing the mobile charge density as an explicit function of the terminal voltages. It allows to greatly reduce the computation time without losing any accuracy. In order to validate the analytical model, we have also developed the 2D simulations of a DG MOSFET structure and performed both static and dynamic electrical simulations of the device. Comparisons with the 2D numerical simulations give evidence for the good behaviour and the accuracy of the model. Finally, we present the VHDL‐AMS code of the DG MOSFET model and related simulation results. Copyright © 2006 John Wiley & Sons, Ltd.     

An analytic drain current model for long‐channel undoped gate stack surrounding‐gate MOSFETs including interface fixed charges

On the basis of the exact solution of Poisson's equation and Pao–Sah double integral for long‐channel bulk MOSFETs, a continuous and analytic drain current model for the undoped gate stack (GS) surrounding‐gate (SRG) metal–oxide–semiconductor field‐effect transistor (MOSFET) including positive or negative interface fixed charges near the drain junction is presented. Considering the effect of the interface fixed charges on the flat‐band voltage and the electron mobility, the model, which is expressed with the surface and body center potentials evaluated at the source and drain ends, describes the drain current from linear region to saturation region through a single continuous expression. It is found that the surface and body center potentials are increased/decreased in the case of positive/negative interface fixed charges, respectively, and the positive/negative interface fixed charges can decrease/increase the drain current. The model agrees well with the 3D numerical simulations and can be efficiently used to explore the effects of interface fixed charges on the drain current of the gate stack surrounding‐gate MOSFETs of the charge‐trapped memory device. Copyright © 2013 John Wiley & Sons, Ltd.     

Full Quantum Mechanical Simulation of Ultra-Small Silicon Devices in Three-Dimensions: Physics and Issues

The combination of the need for alternative devices and the improvement in process technology has led to the examination of silicon quantum wires for future MOS technology. However, in order to properly model these devices, a full three-dimensional quantum mechanical treatment is required. In this paper, we present the results of a three-dimensional, fully quantum mechanical, self-consistent simulation of a silicon quantum wire MOSFET (Metal Oxide Field Effect Transistor) with a narrow channel (8 nm). A quasi-standing wave is formed in the narrow channel at certain gate voltages as the electron density is trapped in narrow channel. These effects are the result of two competing effects: (1) the interaction of the propagating electrons with the channel dopants, as well as with the dopants in the source and drain of the device. (2) the reflections from the boundaries that form the narrow channel both on the source side and the drain side.     

Study of fluctuations in advanced MOSFETs using a 3D finite element parallel simulator

Two important new sources of fluctuations in nanoscaled MOSFETs are the polysilicon gates and the introduction of high-κ gate dielectrics. Using a 3D parallel drift-diffusion device simulator, we study the influence of the polycrystal grains in polysilicon and in the high-κ dielectric on the device threshold for MOSFETs with gate lengths of 80 and 25 nm. We model the surface potential pinning at the grain boundaries in polysilicon through the inclusion of an interfacial charge between the grains. The grains in the high-κ gate dielectric are distinguished by different dielectric constants. We have found that the largest impact of the polysilicon grain boundary in the 80 nm gate length MOSFET occurs when it is positioned perpendicular to the current flow. At low drain voltage the maximum impact occurs when the grain boundary is close to the middle of the gate. At high drain voltage the impact is stronger when the boundary is moved toward the source end of the channel. Similar behaviour is observed in the 25 nm gate length MOSFET.     

一种电流型D类功放高频自激驱动电路

为了解决物理美容设备中电流型D类功放自激驱动栅源电压过高的问题,设计了一种实用电流型D类功放的高频自激驱动电路。通过改变电路中直流偏置电压、MOS管驱动级的电容、漏源间的电容以及两管漏极间电容、供电电压的方法,解决驱动栅源电压过高的问题。通过理论和试验分析,完成电路的设计。通过试验,做到了栅源电压不超过±30V,谐振频率可以达到2MHz左右。该电路具有分离元件少,结构简单,效率高等优点。将该电路实际应用到一款物理美容设备中时,达到了很好的消脂、美白、嫩肤效果。     

A study of threshold voltage fluctuations of nanoscale double gate metal-oxide-semiconductor field effect transistors using quantum correction simulation

In this paper, we computationally investigate fluctuations of the threshold voltage introduced by random dopants in nanoscale double gate metal-oxide-semiconductor field effect transistors (DG MOSFETs). To calculate variance of the threshold voltage of nanoscale DG MOSFETs, a quantum correction model is numerically solved with the perturbation and the monotone iterative techniques. Fluctuations of the threshold voltage resulting from the random dopant, the gate oxide thickness, the channel film thickness, the gate channel length, and the device width are calculated. Quantum mechanical and classical results have similar prediction on fluctuations of the threshold voltage with respect to different designing parameters including dimension of device geometry as well as the channel doping. Fluctuation increases when the channel doping, the channel film thickness, and/or the gate oxide thickness increase. On the other hand, it decreases when the channel length and/or the device width increase. Calculations of the quantum correction model are quantitatively higher than that of the classical estimation according to different quantum confinement effects in nanoscale DG MOSFETs. Due to good channel controllability, DG MOSFETs possess relatively lower fluctuation, compared with the fluctuation of single gate MOSFETs (less than a half of the fluctuation[-11pc] of SG MOSFETs). To reduce fluctuations of the threshold voltage, epitaxial layers on both sides of channel with different epitaxial doping are introduced. For a certain thickness of epitaxial layers, the fluctuation of the threshold voltage decreases when epitaxial doping decreases. In contrast to conventional quantum Monte Carlo approach and small signal analysis of the Schrödinger-Poisson equations, this computationally efficient approach shows acceptable accuracy and is ready for industrial technology computer-aided design application.     

Degeneracy and High Doping Effects in Deep Sub-Micron Relaxed and Strained Si n-MOSFETs

Conventional scaling of modern semiconductor (MOSFET) devices to nano metre dimensions leads to ever-increasing doping levels both within the contacts (source and drain) and the channel region. Thus the carrier statistics governing the device operation become Fermi-Dirac in nature rather than Maxwell-Boltzmann. The effect of degeneracy becomes of even greater importance as strained materials such as strained-Si, are considered due to a decrease in the effective density of states. Additionally since the supply voltage does not scale as fast as the device dimensions, carrier transport takes place within a non-equilibrium/heated Fermi-Dirac distribution. Thus it is necessary to adopt simulation techniques such as ensemble Monte Carlo that includes non-equilibrium transport.     

A compact interband tunneling current model for Gate-on-Source/Channel SOI-TFETs

A tunneling probability-based drain current model for tunnel field-effect transistors (FETs) is presented. First, an analytical model for the surface potential and the potential at the channel–buried oxide interface is derived for a Gate-on-Source/Channel silicon on insulator (SOI)-tunnel FET (TFET), considering the effect of the back-gate voltage. Next, a drain current model is derived for the same device by using the tunneling probability at the source–channel junction. The proposed model includes physical parameters such as the gate oxide thickness, buried oxide thickness, channel thickness, and front-gate oxide dielectric constant. The proposed model is used to investigate the effects of variation of the front-gate voltage, drain voltage, back-gate voltage, and front-gate dielectric thickness. Moreover, a threshold voltage model is developed and the drain-induced barrier lowering (DIBL) is calculated for the proposed device. The effect of bandgap narrowing is considered in the model. The model is validated by comparison with Technology Computer-Aided Design (TCAD) simulation results.