Impact of Channel Thickness on the Performance of GaAs and GaSb DG-JLMOSFETs: An Atomistic Tight Binding Based Evaluation

Islam, Md. Shahidul; Hasan, Md. Soyaeb; Islam, Md. Rafiqul; Iskanderani, Ahmed I.; Mehedi, Ibrahim M.; Hasan, Md. Tanvir

doi:10.1109/access.2021.3106141

Cited by 13 publications

(4 citation statements)

References 59 publications

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“…In all four FinFETs, increasing fin dielectric constants results in lower threshold voltages. Notably, GaAs-FinFET shows a considerable decline in threshold voltage with a fin dielectric constant of 45, achieving the lowest value of 0.454 V among the simulated FinFETs the at gate and fin dielectric constants of 20 and 45 (20,45) in Fig. 2; 25 and 45 (25, 45) in Fig.…”

Section: Threshold Voltage At the Gate Dielectric Constant Of 20 And ...mentioning

confidence: 93%

Optimizing dielectric constants for enhanced performance in nanoscale DG-FinFETs: A comprehensive study on short channel effects

Nura Muhammad Shehu,

Garba Babaji,

Mutari Hajara Ali

2024

IJBAS

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This study explores how variations in fin and gate dielectric constants impact nanoscale, DG-FinFETs’ sensitivity to Short Channel Effects (SCEs). Various fin (channel) materials; Gallium Arsenide (GaAs), Gallium Antimonide (GaSb), Gallium Nitride (GaN), and Silicon (Si), are considered. PADRE simulation environment is used to investigate the threshold Voltage (Vth) Roll-off, a crucial performance parameter. GaAs-FinFET, with a gate dielectric and fin dielectric constant values of 15 and 45 shows the lowest threshold voltage of 0.412 V. The study concludes that FinFETs with a higher fin dielectric constant than gate dielectric constant exhibit reduced SCEs, leading to lower power consumption, faster switching, and improved efficiency. This underscores the importance of optimizing dielectric constants, especially the fin dielectric constant, for enhanced DG-FinFET performance.

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Section: Threshold Voltage At the Gate Dielectric Constant Of 20 And ...mentioning

confidence: 93%

Optimizing dielectric constants for enhanced performance in nanoscale DG-FinFETs: A comprehensive study on short channel effects

Nura Muhammad Shehu,

Garba Babaji,

Mutari Hajara Ali

2024

IJBAS

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“…The DIBL is defined as the difference in threshold voltage caused by increasing the drain voltage from 0.01 V to 0.05 V [41]. DIBL value can be determined using the formula stated in [42]:…”

Section: Impact Of Electron Mobility Variations On Diblmentioning

confidence: 99%

Effect of electron mobility variation on short channel effects in nanoscale double gate FinFETs: A comparative study

Shehu,

Garba Babaji,

Mutari Hajara Ali

2024

IJPR

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This work investigates the impact of electron mobility variations on short channel effects (SCEs) in different semiconductor materials using FinFETs. Using PADRE simulator, the work examines Gallium Arsenide (GaAs), Gallium Antimonide (GaSb), Gallium Nitride (GaN), and Silicon (Si) FinFETs, analyzing performance metrics such as Drain Induced Barrier Lowering (DIBL), Subthreshold Swing (SS) and Threshold Voltage roll-off. The result shows that GaN-FinFET exhibits lowest subthreshold swing of 63 mV/dec at electron mobility of 10000 cm2/Vs, and threshold voltage of 0.44V at electron mobility of 10000 cm2/Vs, while Si-FinFET exhibits lowest DIBL of 3 mV/V at (4000-10000) cm2/Vs. This finding contributes to advancing the understanding of short channel effects in nanoscale FinFETs and provides valuable insights for optimizing device performance in future semiconductor technologies.

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“…Having mentioned the challenges associated with the existing models, the sp 3 d 5 s * tight-binding (TB) Method [31][32][33][34][35], while being computationally inefficient [36,37] compared to effective mass approximation (EMA) based approaches [38][39][40][41][42], is found to be more accurate in terms of considering effect of confinement [43] and hence the electrostatics parameters such as potential and electron carrier concentration obtained from utilizing the band-structure calculated from TB method (TBM) are more accurate than the parameters obtained from EMA based approaches. Furthermore, with a view to maintaining the accuracy as well as reducing the computational cost of calculating the band-structure of ultra-thin-body (UTB) devices from TBM, a significant k-point based approach is recently reported by Solanki et al [44], where identification of significant k-points around the band-minima, enables accurate determination of the electrostatics for DG-SOI MOS devices.…”

Section: Introductionmentioning

confidence: 99%

Band-structure based electrostatics model for ultra-thin-body double-gate silicon-on-insulator MOS devices

Mishra

Kansal

Solanki

et al. 2023

J. Phys. D: Appl. Phys.

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The effect of Quantum Confinement has become significant in terms of its impact on the scalability and electrostatics of Ultra-Thin-Body Double-Gate MOSFETs. In this paper, we present a simplified model to account for the effect of quantum confinement, considering the contribution of the ground-state and the first excited state of the conduction band, on the electron carrier concentration, which when incorporated into the 1-D Poisson's equation, enables the determination of the electrostatic potential. We establish the accuracy of the proposed model, over a wide range of process and electrical parameters, through aggressively benchmarking the electrostatics parameters obtained from the proposed model with results from the sp3d5s* Tight-Binding Model (TBM), over a wide range of device temperatures. Furthermore, a simplified model for the integrated channel charge density is shown in the form of a diffusion layer charge where the thickness and potential of this layer, while being gate voltage dependent, enables the channel charge density obtained from the model to agree well with results from TBM. Through this physics based and accurate model for the integrated charge, a simplified understanding of the gate capacitance is shown as a series combination of the diffusion layer capacitance, strong-inversion capacitance and oxide capacitance, which includes the effects of structural confinement as well as charge confinement at low and high gate voltages, respectively.

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Impact of Channel Thickness on the Performance of GaAs and GaSb DG-JLMOSFETs: An Atomistic Tight Binding Based Evaluation

Cited by 13 publications

References 59 publications

Optimizing dielectric constants for enhanced performance in nanoscale DG-FinFETs: A comprehensive study on short channel effects

Optimizing dielectric constants for enhanced performance in nanoscale DG-FinFETs: A comprehensive study on short channel effects

Effect of electron mobility variation on short channel effects in nanoscale double gate FinFETs: A comparative study

Band-structure based electrostatics model for ultra-thin-body double-gate silicon-on-insulator MOS devices

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