Asymmetrically Engineered Nanoscale Transistors for On-Demand Sourcing of Terahertz Plasmons

Bilal Barut; Xavier Cantos-Roman; Justin Crabb; Chun Pui Kwan; Ripudaman Dixit; Nargess Arabchigavkani; Shenchu Yin; Jubin Nathawat; Keke He; Michael D. Randle; Farah Vandrevala; Takeyoshi Sugaya; Erik Einarsson; Josep M. Jornet; Jonathan P. Bird; Gregory R. Aizin

doi:10.1021/acs.nanolett.1c04515

Asymmetrically Engineered Nanoscale Transistors for On-Demand Sourcing of Terahertz Plasmons

Bilal Barut
, Xavier Cantos-Roman
, Justin Crabb
, Chun Pui Kwan
, Ripudaman Dixit
, Nargess Arabchigavkani
, Shenchu Yin
, Jubin Nathawat
, Keke He
, Michael D. Randle
, Farah Vandrevala
, Takeyoshi Sugaya
, Erik Einarsson
, Josep M. Jornet
, Jonathan P. Bird
, Gregory R. Aizin

Department of Electrical Engineering

University at Buffalo

SUNY Buffalo
Northeastern University
National Institute of Advanced Industrial Science and Technology
City University of New York

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Terahertz (THz) plasma oscillations represent a potential path to implement ultrafast electronic devices and circuits. Here, we present an approach to generate on-chip THz signals that relies on plasma-wave stabilization in nanoscale transistors with specific structural asymmetry. A hydrodynamic treatment shows how the transistor asymmetry supports plasma-wave amplification, giving rise to pronounced negative differential conductance (NDC). A demonstration of these behaviors is provided in InGaAs high-mobility transistors, which exhibit NDC in accordance with their designed asymmetry. The NDC onsets once the drift velocity in the channel reaches a threshold value, triggering the initial plasma instability. We also show how this feature can be made to persist beyond room temperature (to at least 75 °C), when the gating is configured to facilitate a transition between the hydrodynamic and ballistic regimes (of electron-electron transport). Our findings represent a significant step forward for efforts to develop active components for THz electronics.

Original language	English
Pages (from-to)	2674-2681
Number of pages	8
Journal	Nano Letters
Volume	22
Issue number	7
DOIs	https://doi.org/10.1021/acs.nanolett.1c04515
State	Published - Apr 13 2022

Keywords

Dyakonov-Shur instability
negative differential conductance
plasma waves
plasmonics
terahertz transistors

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10.1021/acs.nanolett.1c04515

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Barut, B., Cantos-Roman, X., Crabb, J., Kwan, C. P., Dixit, R., Arabchigavkani, N., Yin, S., Nathawat, J., He, K., Randle, M. D., Vandrevala, F., Sugaya, T., Einarsson, E., Jornet, J. M., Bird, J. P., & Aizin, G. R. (2022). Asymmetrically Engineered Nanoscale Transistors for On-Demand Sourcing of Terahertz Plasmons. Nano Letters, 22(7), 2674-2681. https://doi.org/10.1021/acs.nanolett.1c04515

@article{146c5f1fb37a457c98f852672ec3ba54,

title = "Asymmetrically Engineered Nanoscale Transistors for On-Demand Sourcing of Terahertz Plasmons",

abstract = "Terahertz (THz) plasma oscillations represent a potential path to implement ultrafast electronic devices and circuits. Here, we present an approach to generate on-chip THz signals that relies on plasma-wave stabilization in nanoscale transistors with specific structural asymmetry. A hydrodynamic treatment shows how the transistor asymmetry supports plasma-wave amplification, giving rise to pronounced negative differential conductance (NDC). A demonstration of these behaviors is provided in InGaAs high-mobility transistors, which exhibit NDC in accordance with their designed asymmetry. The NDC onsets once the drift velocity in the channel reaches a threshold value, triggering the initial plasma instability. We also show how this feature can be made to persist beyond room temperature (to at least 75 °C), when the gating is configured to facilitate a transition between the hydrodynamic and ballistic regimes (of electron-electron transport). Our findings represent a significant step forward for efforts to develop active components for THz electronics.",

keywords = "Dyakonov-Shur instability, negative differential conductance, plasma waves, plasmonics, terahertz transistors",

author = "Bilal Barut and Xavier Cantos-Roman and Justin Crabb and Kwan, \{Chun Pui\} and Ripudaman Dixit and Nargess Arabchigavkani and Shenchu Yin and Jubin Nathawat and Keke He and Randle, \{Michael D.\} and Farah Vandrevala and Takeyoshi Sugaya and Erik Einarsson and Jornet, \{Josep M.\} and Bird, \{Jonathan P.\} and Aizin, \{Gregory R.\}",

year = "2022",

month = apr,

day = "13",

doi = "10.1021/acs.nanolett.1c04515",

language = "English",

volume = "22",

pages = "2674--2681",

journal = "Nano Letters",

issn = "1530-6984",

publisher = "American Chemical Society",

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Barut, B, Cantos-Roman, X, Crabb, J, Kwan, CP, Dixit, R, Arabchigavkani, N, Yin, S, Nathawat, J, He, K, Randle, MD, Vandrevala, F, Sugaya, T, Einarsson, E, Jornet, JM, Bird, JP & Aizin, GR 2022, 'Asymmetrically Engineered Nanoscale Transistors for On-Demand Sourcing of Terahertz Plasmons', Nano Letters, vol. 22, no. 7, pp. 2674-2681. https://doi.org/10.1021/acs.nanolett.1c04515

TY - JOUR

T1 - Asymmetrically Engineered Nanoscale Transistors for On-Demand Sourcing of Terahertz Plasmons

AU - Barut, Bilal

AU - Cantos-Roman, Xavier

AU - Crabb, Justin

AU - Kwan, Chun Pui

AU - Dixit, Ripudaman

AU - Arabchigavkani, Nargess

AU - Yin, Shenchu

AU - Nathawat, Jubin

AU - He, Keke

AU - Randle, Michael D.

AU - Vandrevala, Farah

AU - Sugaya, Takeyoshi

AU - Einarsson, Erik

AU - Jornet, Josep M.

AU - Bird, Jonathan P.

AU - Aizin, Gregory R.

PY - 2022/4/13

Y1 - 2022/4/13

N2 - Terahertz (THz) plasma oscillations represent a potential path to implement ultrafast electronic devices and circuits. Here, we present an approach to generate on-chip THz signals that relies on plasma-wave stabilization in nanoscale transistors with specific structural asymmetry. A hydrodynamic treatment shows how the transistor asymmetry supports plasma-wave amplification, giving rise to pronounced negative differential conductance (NDC). A demonstration of these behaviors is provided in InGaAs high-mobility transistors, which exhibit NDC in accordance with their designed asymmetry. The NDC onsets once the drift velocity in the channel reaches a threshold value, triggering the initial plasma instability. We also show how this feature can be made to persist beyond room temperature (to at least 75 °C), when the gating is configured to facilitate a transition between the hydrodynamic and ballistic regimes (of electron-electron transport). Our findings represent a significant step forward for efforts to develop active components for THz electronics.

AB - Terahertz (THz) plasma oscillations represent a potential path to implement ultrafast electronic devices and circuits. Here, we present an approach to generate on-chip THz signals that relies on plasma-wave stabilization in nanoscale transistors with specific structural asymmetry. A hydrodynamic treatment shows how the transistor asymmetry supports plasma-wave amplification, giving rise to pronounced negative differential conductance (NDC). A demonstration of these behaviors is provided in InGaAs high-mobility transistors, which exhibit NDC in accordance with their designed asymmetry. The NDC onsets once the drift velocity in the channel reaches a threshold value, triggering the initial plasma instability. We also show how this feature can be made to persist beyond room temperature (to at least 75 °C), when the gating is configured to facilitate a transition between the hydrodynamic and ballistic regimes (of electron-electron transport). Our findings represent a significant step forward for efforts to develop active components for THz electronics.

KW - Dyakonov-Shur instability

KW - negative differential conductance

KW - plasma waves

KW - plasmonics

KW - terahertz transistors

UR - https://www.scopus.com/pages/publications/85127388368

U2 - 10.1021/acs.nanolett.1c04515

DO - 10.1021/acs.nanolett.1c04515

M3 - Article

C2 - 35312324

SN - 1530-6984

VL - 22

SP - 2674

EP - 2681

JO - Nano Letters

JF - Nano Letters

IS - 7

ER -

Asymmetrically Engineered Nanoscale Transistors for On-Demand Sourcing of Terahertz Plasmons

Abstract

Keywords

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