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.     

Impact of leakage current in germanium channel based DMDG TFET using drain-gate underlap technique

In this work, a dual metal (DM) double-gate (DG) Tunnel Field Effect Transistor (DMDG-TFET) with drain-gate underlap is proposed to overcome the challenges in conventional TFET. The ON-current (I_on), OFF-current (I_off), I_on/I_off ratio, subthreshold swing (SS) and ambipolar current (I_ambi) of the proposed device with drain underlap are investigated as gate length is scaled (L_GATE) down. The proposed device gives a better suppression in leakage current and low ambipolar current. The suppressed leakage current (I_off) and ambipolar current (I_ambi) are 9.49 × 10⁻¹⁴ A/µm and 1.95 × 10⁻¹² A/µm respectively for a gate length (L_GATE) of 36 nm and a channel length (L_Ch) of 50 nm for a supply voltage of 0.5 V. Excellent switching behavior is achieved when gate length (L_GATE) is 72% of the channel length (L_Ch). The proposed architecture is suitable for low power applications.     

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.     

一种氮化镓高迁移率晶体管的栅电流噪声模型

This work presents a theoretical and experimental study on the gate current 1/f noise in Al Ga N/Ga N HEMTs. Based on the carrier number fluctuation in the two-dimensional electron gas channel of Al Ga N/Ga N HEMTs, a gate current 1/f noise model containing a trap-assisted tunneling current and a space charge limited current is built. The simulation results are in good agreement with the experiment. Experiments show that, if Vg Vx, gate current 1/f noise comes from not only the trap-assisted tunneling RTS, but also the space charge limited current RTS. This indicates that the gate current 1/f noise of the Ga N-based HEMTs device is sensitive to the interaction of defects and the piezoelectric relaxation. It provides a useful characterization tool for deeper information about the defects and their evolution in Al Ga N/Ga N HEMTs.     

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.     

Impact of gate metal work-function engineering for enhancement of subthreshold analog/RF performance of underlap dual material gate DG-FET

This work presents a systematic comparative study of analog/RF performance for underlap dual material gate (U-DMG) DG NMOSFET. In previous works, improved device performances have been achieved by use of high dielectric constant (k) spacer material. Although high-k spacers improve device performance, the intrinsic gain of the device reduces. For the analog circuits applications intrinsic gain is an important parameter. Hence, an optimized spacer material having dielectric constant, k = 7.5 has been used in this study and the gain is improved further by dual-material gate (DMG) technology. In this paper we have also studied the effect of gate material having different work function on the U-DMG DG NMOSFETs. This device exploits a step function type channel potential created by DMG for performance improvement. Different parameters such as the transconductance (g_m), the gain per unit current (g_m/I_ds), the intrinsic gain (g_mR_o), the intrinsic capacitance, the intrinsic resistance, the transport delay and, the inductance of the device have been analyzed for analog and RF performance analysis. Analysis suggested that the average intrinsic gain, g_m/I_d and g_m are increase by 22.988%, 16.10% and 27.871% respectively compared to the underlap single-material gate U-DG NMOSFET.     

Oxide thickness dependent compact model of channel noise for E-mode AlGaN/GaN MOS-HEMT

In this paper, a compact channel noise model for gate recessed enhancement mode GaN based MOS-HEMT which is valid for all regions of operation is proposed. The compact noise model consists of high frequency thermal noise and low frequency flicker noise. The drain current, which is one of the most important parameters for compact noise model is developed by incorporating interface and oxide traps, mobility degradation due to vertical electric field, velocity saturation effect and self-heating effect. The flicker noise model is derived by considering mobility and carrier fluctuation due to traps present in both oxide and interface layer. The thermal noise and flicker noise models are validated by comparing the results with TCAD simulation and experimental results from literature respectively. Effect of thermal and flicker noise power spectral density (PSD) variation with different oxide thickness has also been analyzed.     

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.     

Source/drain extension region engineering in nanoscale double gate SOI MOSFETs: Novel design methodology for low-voltage analog applications

The present paper proposes for the first time, a novel design methodology based on the optimization of source/drain extension (SDE) regions to significantly improve the trade-off between intrinsic voltage gain (A_VO) and cut-off frequency (f_T) in nanoscale double gate (DG) devices. Our results show that an optimally designed 25 nm gate length SDE region engineered DG MOSFET operating at drain current of 10 μA/μm, exhibits up to 65% improvement in intrinsic voltage gain and 85% in cut-off frequency over devices designed with abrupt SDE regions. The influence of spacer width, lateral source/drain doping gradient and symmetric as well as asymmetrically designed SDE regions on key analog figures of merit (FOM) such as transconductance (g_m), transconductance-to-current ratio (g_m/I_ds), Early voltage (V_EA), output conductance (g_ds) and gate capacitances are examined in detail. The present work provides new opportunities for realizing future low-voltage/low-power analog circuits with nanoscale SDE engineered DG MOSFETs.     

A new lifetime prediction method for hot-carrier degradation in n-MOSFETs with ultrathin gate oxides under Vg=Vd

Hot-carrier degradation of n-MOSFETs at high gate voltages (V_g=V_d) is examined. A new lifetime prediction method is developed based on the universal power law between the degradation of saturated drain current (dI_dsat) and the product of the injected charge fluence times the gate current, which is independent of gate or drain voltages. This method is applied to 4 and 5 nm n-MOSFETs and lifetimes are estimated under their operation conditions. It is applicable to n-MOSFETs with ultrathin gate oxides.     

Modeling and simulation of enhancement mode p-GaN Gate AlGaN/GaN HEMT for RF circuit switch applications

An enhancement mode p-GaN gate AlGaN/GaN HEMT is proposed and a physics based virtual source charge model with Landauer approach for electron transport has been developed using Verilog-A and simulated using Cadence Spectre, in order to predict device characteristics such as threshold voltage, drain current and gate capacitance. The drain current model incorporates important physical effects such as velocity saturation, short channel effects like DIBL (drain induced barrier lowering), channel length modulation (CLM), and mobility degradation due to self-heating. The predicted I_d-V_ds, I_d-V_gs, and C-V characteristics show an excellent agreement with the experimental data for both drain current and capacitance which validate the model. The developed model was then utilized to design and simulate a single-pole single-throw (SPST) RF switch.     

Traps centers impact on Silicon nanocrystal memories given by Random Telegraph Signal and low frequency noise

This work reports on a comprehensive process of trapping centers in Silicon nanocrystal (nc-Si) memories devices. The trap centers have been studied using Random Telegraph Signal (RTS) and Low Frequency (LF) techniques. The study of the traps which are responsible for RTS noise in non-volatile memories (NVM) devices as a function of gate voltage and temperature, offers the opportunity of studying the trapping/detrapping behaviour of a single interface trap center. The RTS parameters of the devices having random discrete fluctuations in the drain current get more information about trap energy level and spatial localization from the SiO₂/Si interface. The impact of trap centers has been also investigated showing the significant noise between memories and references devices. Furthermore, it has convincingly been shown that this discrete switching of the drain current between a high and a low state is the basic feature responsible for l/f^γ flicker noise in MOSFETs transistors.     

Scaling behaviors of transient noise current in organic field-effect transistors

Top-contact and bottom-gate organic field-effect transistors (OFETs) based on poly(3-hexylthiophene), P3HT polymer has been fabricated with thermal treatment condition. Transient noise currents of the OFETs are measured at various source–drain voltages ranging from 0 V to ?60 V with respect to a fixed gate voltage of ?60 V. The results from conventional power spectral density method are compared with the more robust Detrended Fluctuation Analysis. The latter has been proven to be reliable for fractal signals particularly in the presence of nonstationary effects. Interesting transitions between multiscaling and monoscaling behaviors are observed in the power spectral density as well as the Detrended Fluctuation Analysis plots for different applied source–drain voltage V_ds. Uncorrelated white noise characteristics are observed for noise current measured at low V_ds, meanwhile 1/f noise-like scaling behaviors are observed at intermediate V_ds. At higher V_ds, the noise characteristics appeared to be close to Brownian-like power-law behavior. The scaling characteristics of the transient noise current can be related to the charge carrier dynamics. It is also found that large numbers of trap centers are induced when the device is stressed at high applied V_ds. The existence of these trap centers would disperse charge carriers, leading to 1/f type noise that could diminish the presence of Brownian noise in a very short time.     

Performance analysis of long Ge channel double gate (DG) p MOSFETs with high-k gate dielectrics based on carrier concentration formulation

In this paper, electrical behavior of symmetric double gate Ge channel MOSFETs with high-k dielectrics is reported on the basis of carrier concentration formalism. The model relies on the solution of Poisson-Boltzmann equations subject to suitable boundary conditions taking into account the effect of interface trap charge density (D_it) and the Pao-Sah’s current formulation considering field dependent hole mobility. It is continuous as it holds good for sub-threshold, weak and strong inversion regions of device operation. The proposed model has been employed to calculate the drain current of DG MOSFETs for different values of gate voltage and drain voltage along with various important device parameters such as transconductance, output conductance, and transconductance per unit drain current for a wide range of interface trap charge density, equivalent oxide thickness (EOT) and bias conditions. Moreover, most of the important device parameters are compared with their corresponding Si counter parts. Accuracy of the model has been verified by comparing analytical results with the numerical simulation data. A notable improvement of the drive current and transconductance for Ge devices is observed with reference to Si devices, particularly when D_it is small.     

Source/drain optimization of underlapped lightly doped nanoscale double-gate MOSFETs

The impact of the spacer length at the source (L_s) and drain (L_d) on the performance of symmetrical lightly-doped double-gate (DG) MOSFET with gate length L = 20 nm is analyzed, with the type and doping concentration of the spacers kept the same as in the channel material. Using the transport parameters extracted from experimental data of a double-gate FinFET, simulations were performed for optimization of the underlapped gate-source/drain structure. The simulation results show that the subthreshold leakage current is significantly suppressed without sacrificing the on-state current for devices designed with asymmetrical source/drain extension regions, satisfying the relations L_s = L/2 and L_d = L. In independent drive configuration, the top-gate response can be altered by application of a control voltage on the bottom-gate. In devices with asymmetrical source/drain extension regions, simulations demonstrate that the threshold voltage controllability is improved when the drain extension region length is increased.     

Gate flicker noise in MOSFET's

A simple technique for measuring the gate flicker noise component in MOS field-effect transistors (MOSFET's) is presented. The method gives an estimate of the ratio of gate to drain flicker noise currents as compared to the ratio for thermal noise. In addition, the degree of correlation between the gate and drain flicker noise components can be obtained.     

Low frequency noise in thin gate oxide MOSFETs

Low frequency, 1/f, noise of the drain current, I_D, fluctuations was measured on a series of Si MOSFETs with the gate oxide thickness, t_ox, varied from 25 to 40 Å by steps of 5 Å. The salient point of this work is a demonstration that, at sufficiently low I_D intensities, a mean low noise level in the MOSFETs is reduced as the gate oxide becomes thinner. This is explained assuming that the noise originates from the electron capture/release on Si/SiO₂ interface/border traps. The flat band voltage fluctuations, observable as noise, are linked then to the oxide charge fluctuations by a factor, that is inversely proportional to the gate capacitance, C_ox, and thus proportional to t_ox. At higher I_D, the results are more complicated, as the access resistance noise is also involved. We provide an interpretation of the ensemble of the data and show that the noise analysis can furnish quantitative estimates of several device characteristics. Device degradation and its consequences for the low frequency noise at higher current levels are also discussed.     

Comparative analysis of the DC performance of DG MOSFETs on highly-doped and near-intrinsic silicon layers

A comparison of dc characteristics of fully depleted double-gate (DG) MOSFETs with respect to low-power circuit applications and device scaling has been performed by two-dimensional device simulation. Three different DG MOSFET structures including a conventional N⁺ polysilicon gate device with highly doped Si layer, an asymmetrical P⁺/N⁺ polysilicon gate device with low doped Si layer and a mid-gap metal gate device with low doped Si layer have been analysed. It was found that DG MOSFET with mid-gap metal gates yields the best dc parameters for given off-state drain leakage current and highest immunity to the variation of technology parameters (gate length, gate oxide thickness and Si layer thickness). It is also found that an asymmetrical P⁺/N⁺ polysilicon gate DG MOSFET design offers comparable dc characteristics, but better parameter immunity to technology tolerances than a conventional DG MOSFET.     

Analysis of Harmonic distortion in asymmetric underlap DG-MOSFET with high-k spacer

In analog and RF circuit applications Harmonic distortion (HD) is an important reliability issue that arises due to non-linear performance of devices. In this paper, the asymmetric underlap double gate MOSFET (AUDG-MOSFET) is analyzed for the HD with high-k spacers. In this analysis the devices are compared for their primary distortion components designated by the second order distortion (HD2), the third order distortion (HD3) and the total harmonic distortion (THD). The distortion characteristics of the device are studied as a function of the gate voltage (V_gs) and the transconductance generation factor (g_m/I_d) considering the influence of drain current (I_d) and the transconductance (g_m). A significant improvement on the HD of the device by using high-k spacers is inferred, thereby ascertaining better reliability for RF applications. In addition to this, the distortion in the output characteristics of Cascode and differential amplifier circuits designed with AUDG-MOSFET device is also analyzed in detail.     

A parasitic resistance measurement method exploiting gate current–density characteristics in ultra-short Schottky-gate FETs

Gate forward current–density characteristics of ultra-short Schottky-gates are studied with experiments and calculation to clarify the mechanism of inhomogeneity in the current density along the gate length. Then, by exploiting the gate current–density characteristics, a new DC measurement method is proposed to evaluate the parasitic source and drain resistances, R_s and R_d, in the Schottky-gate FETs. The method is based on a gate-probing end-resistance technique, which can evaluate the values R_s and R_d simply and accurately by using DC measurement, even if the device has an ultra-short gate length L_g of less than 0.15 μm, because it applies a bias larger than a built-in voltage V_bi of the Schottky junction to the gate electrode in order to eliminate inhomogeneities in the gate current–density characteristics.