Analytical current Model for Dual Material Double Gate Junctionless Transistor

A Transistor model with bulk current is proposed in this article for long channel dual material double gate junction less transistor. The influence of different device parameters such as body thickness, channel length, oxide thickness, and the doping density on bulk current is investigated. The proposed model is validated and compared with simulated data using Cogenda TCAD. The model is designed by Poison’s equation and depletion approximation. Current driving capability of MOSFET is improved by dual material gate compare to single material gate

Impact of Device Parameter Variation on the Electrical Characteristic of N-type Junctionless Nanowire Transistor with High-k Dielectrics

Metallurgical junction and thermal budget are serious constraints in scaling and performance of conventional metal-oxide-semiconductor field-effect transistor (MOSFET). To overcome this problem, junctionless nanowire field-effect transistor (JLNWFET) was introduced. In this paper, we investigate the impact of device parameter variation on the performance of n-type JLNWFET with high-k dielectrics. The electrical characteristic of JLNWFET and the inversion-mode transistor of different gate length (LG) and nanowire diameter (dNW) was compared and analyzed. Different high-k dielectrics were used to get an optimum device structure of JLNWFET. The device was simulated using SDE Tool of Sentaurus TCAD and the I-V characteristics were simulated using Sdevice Tools. Lombardi mobility model and Philips unified mobility model were applied to define its electric field and doping dependent mobility degradation. A thin-film heavily doped silicon nanowire with a gate electrode that controls the flow of current between the source and drain was used. The proposed JLNWFET exhibits high ON-state current (ION) due to the high doping concentration (ND) of 1 x 1019 cm-3 which leads to the improved ON-state to OFF-state current ratio (ION/IOFF) of about 10% than the inversion-mode device for a LG of 7 nm and the silicon dNW of 6 nm. Electrical characteristics such are drain induced barrier lowering (DIBL) and subthreshold slope (SS) were extracted which leads to low leakage current as well as a high ION/IOFF ratio. The performance was improved by introducing silicon dioxide (SiO2) with high-k dielectric materials, hafnium oxide (HfO2) and silicon nitrate (Si3N4). It was found that JLNWFET with HfO2 exhibits better electrical characteristics and performance

FABRICATION AND CHARACTERIZATION OF ACTIVE NANOSTRUCTURES

Three different nanostructure active devices have been designed, fabricated and characterized. Junctionless transistors based on highly-doped silicon nanowires fabricated using a bottom-up fabrication approach are first discussed. The fabrication avoids the ion implantation step since silicon nanowires are doped in-situ during growth. Germanium junctionless transistors fabricated with a top down approach starting from a germanium on insulator substrate and using a gate stack of high-k dielectrics and GeO2 are also presented. The levels and origin of low-frequency noise in junctionless transistor devices fabricated from silicon nanowires and also from GeOI devices are reported. Low-frequency noise is an indicator of the quality of the material, hence its characterization can reveal the quality and perhaps reliability of fabricated transistors. A novel method based on low-frequency noise measurement to envisage trap density in the semiconductor bandgap near the semiconductor/oxide interface of nanoscale silicon junctionless transistors (JLTs) is presented. Low-frequency noise characterization of JLTs biased in saturation is conducted at different gate biases. The noise spectrum indicates either a Lorentzian or 1/f. A simple analysis of the low-frequency noise data leads to the density of traps and their energy within the semiconductor bandgap. The level of noise in silicon JLT devices is lower than reported values on transistors fabricated using a top-down approach. This noise level can be significantly improved by improving the quality of dielectric and the channel interface

Performance analysis of ultrathin junctionless double gate vertical MOSFETs

The main challenge in MOSFET minituarization is to form an ultra-shallow source/drain (S/D) junction with high doping concentration gradient, which requires an intricate S/D and channel engineering. Junctionless MOSFET configuration is an alternative solution for this issue as the junction and doping gradients is totally eliminated. A process simulation has been developed to investigate the impact of junctionless configuration on the double-gate vertical MOSFET. The result proves that the performance of junctionless double-gate vertical MOSFETs (JLDGVM) are superior to the conventional junctioned double-gate vertical MOSFETs (JDGVM). The results reveal that the drain current (ID) of the n-JLVDGM and p-JLVDGM could be tremendously enhanced by 57% and 60% respectively as the junctionless configuration was applied to the double-gate vertical MOSFET. In addition, junctionless devices also exhibit larger ION/IOFF ratio and smaller subthreshold slope compared to the junction devices, implying that the junctionless devices have better power consumption and faster switching capability

Geometric and process design of ultra-thin junctionless double gate vertical MOSFETs

The junctionless MOSFET architectures appear to be attractive in realizing the Moore’s law prediction. In this paper, a comprehensive 2-D simulation on junctionless vertical double-gate MOSFET (JLDGVM) under geometric and process consideration was introduced in order to obtain excellent electrical characteristics. Geometrical designs such as channel length (Lch) and pillar thickness (Tp) were considered and the impact on the electrical performance was analyzed. The influence of doping concentration and metal gate work function (WF) were further investigated for achieving better performance. The results show that the shorter Lch can boost the drain current (ID) of n-JLDGVM and p-JLDGVM by approximately 68% and 70% respectively. The ID of the n-JLVDGM and p-JLVDGM could possibly boost up to 42% and 78% respectively as the Tp is scaled down from 11nm to 8nm. The channel doping (Nch) is also a critical parameter, affecting the electrical performance of both n-JLDGVM and p-JLDGVM in which 15% and 39% improvements are observed in their respective ID as the concentration level is increased from 1E18 to 9E18 atom/cm3. In addition, the adjustment of threshold voltage can be realized by varying the metal WF

Multi-gate Si nanowire MOSFETs:fabrication, strain engineering and transport analysis

Multi-gate devices e.g. gate-all-around (GAA) Si nanowires and FinFETs are promising can- didates for aggressive CMOS downscaling. Optimum subthreshold slope, immunity against short channel effect and optimized power consumption are the major benefits of such archi- tectures due to higher electrostatic control of the channel. On the other hand, Si nanowires show excellent mechanical properties e.g. yield and fracture strengths of 10±2% and 30±1% in comparison to 3.7% and 4.0% for bulk Si, respectively, a strong motivation to be used as exclusive platforms for innovative nanoelectronic applications e.g. novel strain engineering techniques for carrier transport enhancement in multi-gate 3D suspended channels or lo- cal band-gap modulation using > 4 GPa uniaxial tensile stress in suspended Si channels to enhance the band-to-band tunneling current in multi-gate Tunnel-FETs, all without plastic deformation and therefore, no carrier mobility degradation in deeply scaled channels. In this thesis and as a first step, a precise built-in stress analysis during local thermal oxidation of suspended Si NWs in the presence of a Si3N4 tensile hard mask was done. Accumulation of up to 2.6 GPa uniaxial tensile stress in the buckled NWs is reported. The contribution of hard mask/spacer engineering on the stress level and the NW formation was studied and buckled self-aligned dual NW MOSFETs on bulk Si with two sub-100 nm cross-sectional Si cores including ∼0.8 uniaxial tensile stress are reported. Micro-Raman spectroscopy was widely used in this thesis to measure stress in the buckled NWs on both bulk and SOI substrates. A process flow was designed to make dense array of GAA sub-5 nm cross-sectional Si NWs using a SOI substrate including a high level of stress. The NW stress level can be engineered simply using e.g. metal-gate thin film stress suitable for both NMOS and PMOS devices. Lately, highly and heavily doped architectures with a single-type doping profile from source to drain, called junctionless and accumulation-mode devices, are proposed to significantly simplify the fabrication process, address a few technical limitations e.g. ultra-abrupt junctions in order to fabricate shorter channel length devices. Therefore, in this process flow, a highly doped accumulation-mode was targeted as the operation mechanism. Finally, extensive TCAD device simulation was done on GAA Si NW JL MOSFETs to study the corner effects on the device characteristics, from subthreshold to strong accumulation, report the concept of local volume accumulation/depletion, quantum flat-band voltage, significant bias-dependent series resistance in junctionless MOSFETs and finally, support the experimental data to extract precisely the carrier mobility in sub-5 nm Si NW MOSFETs

Multigate MOSFETs for digital performance and high linearity, and their fabrication techniques

The aggressive downscaling of complementary metal–oxide–semiconductor (CMOS) technology is facing great challenges to overcome severe short-channel effects. Multigate MOSFETs are one of the most promising candidates for scaling beyond Si CMOS, due to better electrostatic control as compared to conventional planar MOSFETs. Conventional dry etching-induced surface damage is one of the main sources of performance degradation for multigate transistors, especially for III-V high mobility materials. It is also challenging to increase the fin aspect ratio by dry etching because of the non-ideal anisotropic etching profile. Here, we report a novel method, inverse metal-assisted chemical etching (i-MacEtch), in lieu of conventional RIE etching, for 3D fin channel formation. InP junctionless FinFETs with record high-aspect-ratio (~ 50:1) fins are demonstrated by this method for the first time. The i-MacEtch process flow eliminates dry-etching-induced plasma damage, high energy ion implantation damage, and high temperature annealing, allowing for the fabrication of InP fin channels with atomically smooth sidewalls. The sidewall features resulting from this unique and simplified process ensure high interface quality between high-k dielectric layer and InP fin channel. Experimental and theoretical analyses show that high-aspect-ratio FinFETs, which could deliver more current per area under much relaxed horizontal geometry requirements, are promising in pushing the technology node ahead where conventional scaling has met its physical limits. The performance of the FinFET was further investigated through numerical simulation. A new kind of FinFET with asymmetric gate and source/drain contacts has been proposed and simulated. By benchmarking with conventional symmetric FinFET, better short-channel behavior with much higher current density is confirmed. The design guidelines are provided. The overall circuit delay can be minimized by optimizing gate lengths according to different local parasites among circuits in interconnection-delay-dominated SoC applications. Continued transistor scaling requires even stronger gate electrostatic control over the channel. The ultimate scaling structure would be gate-all-around nanowire MOSFETs. We demonstrate III-V junctionless gate-all-around (GAA) nanowire (NW) MOSFETs for the first time. For the first time, source/drain (S/D) resistance and thermal budget are minimized by regrowth using metalorganic chemical vapor deposition (MOCVD) in III-V MOSFETs. The fabricated short-channel (Lg=80 nm) GaAs GAA NWFETs with extremely narrow nanowire width (WNW= 9 nm) show excellent transconductance (gm) linearity at biases (300 mV), characterized by the high third intercept point (2.6 dBm). The high linearity is especially important for low power applications because it is insensitive to bias conditions

Effect Of Channel Length Variation On Analog And RF Performance Of Junctionless Double Gate Vertical Mosfet

This paper investigates the effect of channel length (Lch) variation upon analogue and radio frequency (RF) performance of Junctionless Double Gate Vertical MOSFET (JLDGVM). The study has been performed under the fixed level of process parameters by considering the dependence of analogue and RF properties on the channel length. Furthermore, this paper aims to give a comprehensive insight on possible improvement in the performance of analogue and RF of the JLDGVM device. The structure and characteristics of the device are developed and extracted respectively via 2D TCAD simulation. The results show that both transconductance generation factor (TGF) and transconductance (gm) of the JLDGVM device are tremendously increased by 83% and 74% respectively as the scale of channel length is reduced from 12 nm to 9 nm. On the other hand, the unity gain cut-off frequency (fT) and the gain-band-width product (GBW) tremendously improved by ~93% and ~74% respectively as the channel length of the device is scaled from 12 nm to 9 nm