Layer‐Controlled Low‐Power Tunneling Transistors Based on SnS Homojunction

Liang, Jiakun; Li, Hong; Liu, Fengbin; Lü, Jing

doi:10.1002/adts.202000290

Cited by 7 publications

(3 citation statements)

References 64 publications

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“…The MX materials are also found to be effective for hetero-tunneling junction design by varying layer thickness at different regions of nanoscale TFET. In this line, using a bilayer SnS in source/drain regions with monolayer SnS in the channel region, a SS below 50 mV/dec over four orders of current has been demonstrated 108 .…”

Section: Tfets Based On Metal Mono-chalcogenidesmentioning

confidence: 96%

2D materials-based nanoscale tunneling field effect transistors: current developments and future prospects

et al. 2022

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The continuously intensifying demand for high-performance and miniaturized semiconductor devices has pushed the aggressive downscaling of field-effect transistors (FETs) design. However, the detrimental short-channel effects and the fundamental limit on the sub-threshold swing (SS) in FET have led to a drastic increase in static and dynamic power consumption. The operational limit of nanoscale transistors motivates the exploration of post-CMOS devices like Tunnel FET (TFET), having steeper SS and immunity toward short channel effects. Thus the field of nanoscale 2D-TFET has gained compelling attention in recent times. The nanoscale TFET, with two-dimensional (2D) semiconductor materials, has shown a significant improvement in terms of higher on-state current and lower sub-threshold swing. In this context, the review presented here has comprehensively covered the gradual development and present state-of-arts in the field of nanoscale 2D-TFET design. The relative merits and demerits of each class of 2D materials are identified, which sheds light on the specific design challenges associated with individual 2D materials. Subsequently, the potential device/material co-optimization strategies for the development of efficient TFET designs are highlighted. Next, the experimental development in 2D-TFET design is discussed, and specific synthesis/fabrication challenges for individual material systems are indicated. Finally, an extensive comparative performance study is presented between the simulated as well as experimentally reported potential 2D materials and state-of-the-art bulk material-based TFETs.

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Section: Tfets Based On Metal Mono-chalcogenidesmentioning

confidence: 96%

2D materials-based nanoscale tunneling field effect transistors: current developments and future prospects

et al. 2022

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“…The good electrical conductivity of the material initiated faster NRR charge-transfer kinetics. 105 The potential determining step being *NH 2 + H + + e À -*NH 3 , this catalyst followed the alternating pathway for NRR at the cost of a low energy barrier. However, an elaborate study by Li et al on Fe-based borides suggested that, Fe and B can synergistically act as active sites for NRR.…”

Section: Transition Metal Borides (Tmbs)mentioning

confidence: 99%

Electrochemical ammonia synthesis: fundamental practices and recent developments in transition metal boride, carbide and nitride-class of catalysts

et al. 2022

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“…The introduction of an optimized UL structure can enhance the device performance by increasing the effective channel length and reducing the probability of electron tunneling, which not only suppresses the tunneling current between the source and the drain electrodes in a short channel but also reduces the coupling between the source and the drain and the channel. 63,64 However, the control abilities of the top and bottom gates are limited since the gates do not cover the UL area; if the UL structure is too long, it will adversely reduce the performance of the FET device. Therefore, to achieve the optimized UL length for the Ga 2 SSe FET device, the transfer characteristic curves and the corresponding I on data with different UL lengths are represented in Fig.…”

Section: On-state Currentmentioning

confidence: 99%

Comprehensive understanding of intrinsic mobility and sub-10 nm quantum transportation in Ga₂SSe monolayer

Shen

Cai

et al. 2022

Phys. Chem. Chem. Phys.

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Layer‐Controlled Low‐Power Tunneling Transistors Based on SnS Homojunction

Cited by 7 publications

References 64 publications

2D materials-based nanoscale tunneling field effect transistors: current developments and future prospects

2D materials-based nanoscale tunneling field effect transistors: current developments and future prospects

Electrochemical ammonia synthesis: fundamental practices and recent developments in transition metal boride, carbide and nitride-class of catalysts

Comprehensive understanding of intrinsic mobility and sub-10 nm quantum transportation in Ga₂SSe monolayer

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Layer‐Controlled Low‐Power Tunneling Transistors Based on SnS Homojunction

Cited by 7 publications

References 64 publications

2D materials-based nanoscale tunneling field effect transistors: current developments and future prospects

2D materials-based nanoscale tunneling field effect transistors: current developments and future prospects

Electrochemical ammonia synthesis: fundamental practices and recent developments in transition metal boride, carbide and nitride-class of catalysts

Comprehensive understanding of intrinsic mobility and sub-10 nm quantum transportation in Ga2SSe monolayer

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Product

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Comprehensive understanding of intrinsic mobility and sub-10 nm quantum transportation in Ga₂SSe monolayer