Modeling and Significance of Fringe Capacitance in Nonclassical CMOS Devices With Gate–Source/Drain Underlap

Parasitic gate–source/drain (G–S/D) fringe capacitance in nonclassical nanoscale CMOS devices, e.g., double-gate (DG) MOSFETs, is shown, using two-dimensional numerical simulations, to be very significant, gate bias-dependent, and substantially reduced by a well-designed G–S/D underlap. Analytical modeling of the outer and inner components of the fringe capacitance is developed and verified by the numerical simulations; a BOX-fringe component is modeled for single-gate fully depleted silicon-on-insulator MOSFETs. With the new modeling implemented in UFDG, our process/physics-based generic compact model for DG MOSFETs, UFDG/Spice3 shows how nanoscale DG CMOS speed is severely affected by the fringe capacitance and how this effect can be moderated by an optimal underlap, which yields a good tradeoff between the parasitic capacitance and the S/D resistance.     

The effect of high-K gate dielectrics on deep submicrometer CMOSdevice and circuit performance

The potential impact of high permittivity gate dielectrics on device short channel and circuit performance is studied over a wide range of dielectric permittivities (K_gate) using two-dimensional (2-D) device and Monte Carlo simulations. The gate-to-channel capacitance and parasitic fringe capacitances are extracted using a highly accurate three-dimensional (3-D) capacitance extractor. It is observed that there is a decrease in parasitic outer fringe capacitance and gate-to-channel capacitance in addition to an increase in internal fringe capacitance, when the conventional silicon dioxide is replaced by a high-K gate dielectric. The lower parasitic outer fringe capacitance is beneficial for the circuit performance, while the increase in internal fringe capacitance and the decrease in the gate-to-channel capacitance will degrade the short channel performance contributing to higher DIBL, drain leakage, and lower noise margin. It is shown that using low-K gate sidewalls with high-K gate insulators can decrease the fringing-induced barrier lowering. Also, from the circuit point of view, for the 70-nm technology generation, the presence of an optimum K_gate for different target subthreshold leakage currents has been identified     

Nanoscale FinFETs with gate-source/drain underlap

Using two-dimensional numerical device simulations, we show that optimally designed nanoscale FinFETs with undoped bodies require gate-source/drain (G-S/D) underlap that can be effectively achieved via large, doable straggle in the S-D fin-extension doping profile without causing S-D punch-through. The effective underlap significantly relaxes the fin-thickness requirement for control of short-channel effects (SCEs) via a bias-dependent effective channel length (L/sub eff/), which is long in weak inversion and approaches the gate length in strong inversion. Dependence of L/sub eff/ on the S/D doping profile defines a design tradeoff regarding SCEs and S/D series resistance that can be optimized, depending on the fin width, via engineering of the doping profile in the S/D fin-extensions. The noted optimization is exemplified via a well-tempered FinFET design with an 18-nm gate length, showing further that designs with effective underlap yield minimal parasitic capacitance and reduce leakage components such as gate-induced drain leakage current.     

Analytical modelling of threshold voltage for underlap Fully Depleted Silicon-On-Insulator MOSFET

In this article, surface-potential-based analytical threshold voltage model for underlap Fully Depleted Silicon-On-Insulator MOSFET (underlap-SOI) is developed by solving two-dimensional Poisson equation. The gate underlap at source/drain (S/D) has different boundary conditions as compared to channel region under the gate dielectric that divide the whole channel into three regions. It leads us to derive the new surface potential model for three different channel regions, i.e. the region under the gate dielectric and two gate underlap regions at S/D. The effects of underlap length, channel length, body thickness, channel doping concentration, metal gate work function and gate dielectric constant on threshold voltage have been included in our model. The threshold voltage dependence on different device parameters has been studied using analytical model and simulations. The closeness between the simulation results and model results show that the analytical model accurately calculate the threshold voltage values for large range of device parameters.     

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.     

Impact of geometry-dependent parasitic capacitances on the performance of CNFET circuits

Intrinsic carbon-nanotube field-effect transistors (CNFETs) have been shown to have superior performance over silicon transistors. In this letter, we provide an insight how the parasitic fringe capacitance in state-of-the-art CNFET geometries impacts the overall performance of CNFET circuits. We show that unless the device (gate) width can be significantly reduced, the effective gate capacitance of CNFET will be strongly dominated by the parasitic fringe capacitances, and the superior performance of intrinsic CNFET over silicon MOSFET cannot be achieved in circuit.     

Modeling of cylindrical surrounding gate MOSFETs including the fringing field effects

A physically based analytical model for surface potential and threshold voltage including the fringing gate capacitances in cylindrical surround gate(CSG) MOSFETs has been developed.Based on this a subthreshold drain current model has also been derived.This model first computes the charge induced in the drain/source region due to the fringing capacitances and considers an effective charge distribution in the cylindrically extended source/drain region for the development of a simple and compact model.The fringing gate capacitances taken into account are outer fringe capacitance,inner fringe capacitance,overlap capacitance,and sidewall capacitance.The model has been verified with the data extracted from 3D TCAD simulations of CSG MOSFETs and was found to be working satisfactorily.     

Compact modeling of the effects of parasitic internal fringe capacitance on the threshold voltage of high-k gate-dielectric nanoscale SOI MOSFETs

A compact model for the effect of the parasitic internal fringe capacitance on the threshold voltage of high-k gate-dielectric silicon-on-insulator MOSFETs is developed. The authors' model includes the effects of the gate-dielectric permittivity, spacer oxide permittivity, spacer width, gate length, and the width of an MOS structure. A simple expression for the parasitic internal fringe capacitance from the bottom edge of the gate electrode is obtained and the charges induced in the source and drain regions due to this capacitance are considered. The authors demonstrate an increase in the surface potential along the channel due to these charges, resulting in a decrease in the threshold voltage with an increase in the gate-dielectric permittivity. The accuracy of the results obtained using the authors' analytical model is verified using two-dimensional device simulations.     

Comparison of contact resistance between accumulation-mode and inversion-mode multigate FETs

The performances of accumulation-mode and inversion-mode multigate FETs are compared. The influence of gate underlap on the electrical properties is analyzed. Both simulation results and experimental data show that in a device with gate underlap, accumulation-mode devices have a higher current drive, lower source and drain resistance and less process variability than inversion-mode FETs.     

Impact of High-k Gate Dielectrics on the Device and Circuit Performance of Nanoscale FinFETs

The impact of high-k gate dielectrics on device short-channel and circuit performance of fin field-effect transistors is studied over a wide range of dielectric permittivities k. It is observed that there is a decrease in the parasitic outer fringe capacitance C_of in addition to an increase in the internal fringe capacitance C_if with high-k dielectrics, which degrades the short-channel effects significantly. It is shown that fin width scaling is the most suitable approach to recover the degradation in the device performance due to high-k integration. Furthermore, from the circuit perspective, for the 32-nm technology generation, the presence of an optimum k for a given target subthreshold leakage current has been identified by various possible approaches such as fin width scaling, fin-doping adjustment, and gate work function engineering     

Optimum design of a 4-Gbit/s GaAs MESFET optical preamplifier

An analysis for determining the optimum MESFET gate width to optimize the sensitivity of a high-speed optical preamplifier is presented. A full MESFET model is employed including correlated gate and drain noise sources. The design of an optimum sensitivity monolithic shunt feedback amplifier, including stability requirements, is investigated. The results show that the optimum gate width for minimizing input equivalent noise is significantly larger than earlier simplfied predictions. A sensitivity improvement of 1.2 dB is demonstrated for a 4-Gbit/s MESFET optical amplifier, and results showing the dependence of optimum FET width on photodetector capacitance are described.     

Analysis of flicker and thermal noise in p-channel Underlap DG FinFET

In this paper, we analyze the flicker and thermal noise model for underlap p-channel DG FinFET in weak inversion region. During the analysis of current and charge model, minimum channel potential i.e. virtual source is considered. Initially, the drain current for both long and short channel of DG FinFET are evaluated and found to be well interpreted with experimental results. Further, the flicker and thermal noise spectral density are derived. The flicker noise power spectral density is compared with published experimental results, which shows a good agreement between proposed model and experimental result. During calculation we have considered variation of scattering parameter and furthermore, the degradation of effective mobility is taken into account for ultrathin body. The variation of structural parameters such as gate length (L_g), body thickness (t_Si) and underlap length (L_un) are also considered. The degradation of gate noise voltage with frequency, underlap length and gate length signify that p-channel DG FinFET device can be a promising candidate for analog and RF applications.     

Flicker and thermal noise in an n-channel underlap DG FinFET in a weak inversion region

We propose an analytical model for drain current and inversion charge in the subthreshold region for an underlap DG FinFET by using the minimum channel potential method,i.e.,the virtual source.The flicker and thermal noise spectral density models are also developed using these charge and current models expression.The model is validated with already published experimental results of flicker noise for DG FinFETs.For an ultrathin body,the degradation of effective mobility and variation of the scattering parameter are considered.The effect of device parameters like gate length L_g and underlap length L_un on both flicker and thermal noise spectral densities are also analyzed.Increasing L_g and L_un,increases the effective gate length,which reduces drain current,resulting in decreased flicker and thermal noise density.A decrease of flicker noise is observed for an increase of frequency, which indicates that the device can be used for wide range of frequency applications.     

Optimum design and fabrication of InAlAs/InGaAs HEMT's on GaAs withboth high breakdown voltage and high maximum frequency of oscillation

A simple model to describe the dependence of the breakdown voltage between gate and drain on width of the gate recess in an InAlAs/InGaAs high electron mobility transistor (HEMT) is presented. In this model, the depletion region laterally spreads to the drain region. It enables us to express the dependence of device parameters on the width of the gate recess. The model suggests that the breakdown voltage increases with the width of the gate recess and then saturates, which is experimentally confirmed. Calculations based on the model show that the maximum frequency of oscillation (f_max) also increases with the width of the gate-recess due to the reduction in both the drain conductance and the gate-to-drain capacitance, and then slightly decreases with the width due to the increase in the source resistance. We fabricated InAlAs/InGaAs HEMT's lattice-mismatched on GaAs substrates with optimum recess-width, and these exhibited both a high breakdown voltage of 14 V and a high f_max of 127 GHz at a gate length of 0.66 μm     

Effect of underlap and gate length on device performance of an AlInN/GaN underlap MOSFET

We investigate the performance of an 18 nm gate length AlInN/GaN heterostructure underlap double gate MOSFET, using 2D Sentaurus TCAD simulation. The device uses lattice-matched wideband Al_0.83In_0.17N and narrowband GaN layers, along with high-k Al₂O₃ as the gate dielectric. The device has an ultrathin body and is designed according to the ITRS specifications. The simulation is done using the hydrodynamic model and interface traps are also considered. Due to the large two-dimensional electron gas (2DEG) density and high velocity, the maximal drain current density achieved is very high. Extensive device simulation of the major device performance metrics such as drain induced barrier lowering (DIBL), subthreshold slope (SS), delay, threshold voltage (V_t), I_on/I_off ratio and energy delay product have been done for a wide range of gate and underlap lengths. Encouraging results for delay, I_on, DIBL and energy delay product are obtained. The results indicate that there is a need to optimize the I_off and SS values for specific logic design. The proposed AlInN/GaN heterostructure underlap DG MOSFET shows excellent promise as one of the candidates to substitute currently used MOSFETs for future high speed applications.     

How crucial is back gate misalignment/oversize in double gate MOSFETs for ultra-low-voltage analog/rf applications?

In the present work, by investigating the influence of source/drain (S/D) extension region engineering (also known as gate-underlap architecture) in planar Double Gate (DG) SOI MOSFETs, we offer new design insights to achieve high tolerance to gate misalignment/oversize in nanoscale devices for ultra-low-voltage (ULV) analog/rf applications. Our results show that (i) misaligned gate-underlap devices perform significantly better than DG devices with abrupt source/drain junctions with identical misalignment, (ii) misaligned gate underlap performance (with S/D optimization) exceeds perfectly aligned DG devices with abrupt S/D regions and (iii) 25% back gate misalignment can be tolerated without any significant degradation in cut–off frequency (f_T) and intrinsic voltage gain (A_VO). Gate-underlap DG devices designed with spacer-to-straggle ratio lying within the range 2.5 to 3.0 show best tolerance to misaligned/oversize back gate and indeed are better than self-aligned DG MOSFETs with non-underlap (abrupt) S/D regions. Impact of gate length and silicon film thickness scaling is also discussed. These results are very significant as the tolerable limit of misaligned/oversized back gate is considerably extended and the stringent process control requirements to achieve self-alignment can be relaxed for nanoscale planar ULV DG MOSFETs operating in weak-inversion region. The present work provides new opportunities for realizing future ULV analog/rf design with nanoscale gate–underlap DG MOSFETs.     

An improved two-frequency method of capacitance measurement forSrTiO3 as high-k gate dielectric

An improved two-frequency method of capacitance measurement for the high-k gate dielectrics is proposed. The equivalent circuit model of the MOS capacitor including the four parameters of intrinsic capacitance, loss tangent, parasitic series inductance, and series resistance is developed. These parameters can be extracted by independently measuring the capacitor at two different frequencies. This technique is demonstrated for high-k SrTiO₃ gate dielectrics and the results show that the calibrated capacitances are invariant over a wide range of frequency. In addition, the extracted loss tangent, inductance and resistance are independent on gate voltage and frequency. The effect of series resistance on the frequency dispersion of the capacitance can be also explained by this model. These results indicate that this modified technique can be incorporated in the routine capacitance-voltage (C-V) measurement procedure providing the physically meaningful data for the high-k gate dielectrics     

14 nm FinFET栅围寄生电容的建模与拟合

提出了一种基于保角映射方法的14 nm鳍式场效应晶体管(FinFET)器件栅围寄生电容建模的方法。对FinFET器件按三维几何结构划分寄生电容的种类,再借助坐标变换推导出等效电容计算模型,准确表征了不同鳍宽、鳍高、栅高和层间介质材料等因素对寄生电容的依赖关系。为了验证该寄生电容模型的准确性,对不同结构参数的寄生电容进行三维TCAD仿真。结果表明,模型计算结果与仿真结果的拟合度好,准确地反映了器件结构与寄生电容之间的依赖关系。     

Analysis of the channel inversion layer capacitance in the very thin-gate IGFET

As the gate insulator thickness approaches the channel thickness, the gate capacitance is speculated to be smaller than its gate insulator capacitance. The gate capacitance of the thin-gate IGFET is calculated using Maxwell-Boltzmann and Fermi-Dirac statistics and is experimentally measured. The results show that the gate capacitance approaches the gate insulator capacitance regardless of the gate thickness within the practical range (T_{ox} > 50Å). To explain why the channel thickness is not reflected in the measured gate capacitance, the channel inversion layer capacitance is analyzed numerically. Based on that, its effects on the gate capacitance are discussed quantitatively and an equivalent circuit is proposed.     

Modeling of gate underlap junctionless double gate MOSFET as bio-sensor

In this work, the sensitivity of two types gate underlap Junctionless Double Gate Metal-Oxide-Semiconductor Field-Effect Transistor (JL DG MOSFET) has been compared when the analytes bind in the underlap region. Gate underlap region considered at source end and drain end once at a time in the channel of JL DG MOSFET. Separate models have been derived for both types of gate underlap JL DG MOSFETs and verified through device simulation TCAD tool sprocess and sdevice. To detect the bio-molecules, Dielectric Modulation technique has been used. The shift in the threshold voltage has been pondered as the sensing parameter to detect the presence of biomolecules when they are bound in gate underlap channel region of the devices.