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Title: Planar quantum transistor based on 2D{endash}2D tunneling in double quantum well heterostructures

Abstract

We report on our work on the double electron layer tunneling transistor (DELTT), based on the gate control of two-dimensional{endash}two-dimensional (2D{endash}2D) tunneling in a double quantum well heterostructure. While previous quantum transistors have typically required tiny laterally defined features, by contrast the DELTT is entirely planar and can be reliably fabricated in large numbers. We use a novel epoxy-bond-and-stop-etch flip-chip process, whereby submicron gating on opposite sides of semiconductor epitaxial layers as thin as 0.24 {mu}m can be achieved. Because both electron layers in the DELTT are 2D, the resonant tunneling features are unusually sharp, and can be easily modulated with one or more surface gates. We demonstrate DELTTs with peak-to-valley ratios in the source-drain I{endash}V curve of order 20:1 below 1 K. Both the height and position of the resonant current peak can be controlled by gate voltage over a wide range. DELTTs with larger subband energy offsets ({approximately}21 meV) exhibit characteristics that are nearly as good at 77 K, in good agreement with our theoretical calculations. Using these devices, we also demonstrate bistable memories operating at 77 K. Finally, we briefly discuss the prospects for room temperature operation, increases in gain and high speed. {copyright} {ital 1998 Americanmore » Institute of Physics.}« less

Authors:
; ; ; ; ; ; ;  [1]
  1. Sandia National Laboratories, Albuquerque, New Mexico 87185-1415 (United States)
Publication Date:
OSTI Identifier:
663679
Resource Type:
Journal Article
Journal Name:
Journal of Applied Physics
Additional Journal Information:
Journal Volume: 84; Journal Issue: 10; Other Information: PBD: Nov 1998
Country of Publication:
United States
Language:
English
Subject:
42 ENGINEERING NOT INCLUDED IN OTHER CATEGORIES; TUNNEL EFFECT; HETEROJUNCTIONS; JUNCTION TRANSISTORS; MEMORY DEVICES; OPERATION; RESONANCE

Citation Formats

Simmons, J A, Blount, M A, Moon, J S, Lyo, S K, Baca, W E, Wendt, J R, Reno, J L, and Hafich, M J. Planar quantum transistor based on 2D{endash}2D tunneling in double quantum well heterostructures. United States: N. p., 1998. Web. doi:10.1063/1.368610.
Simmons, J A, Blount, M A, Moon, J S, Lyo, S K, Baca, W E, Wendt, J R, Reno, J L, & Hafich, M J. Planar quantum transistor based on 2D{endash}2D tunneling in double quantum well heterostructures. United States. https://doi.org/10.1063/1.368610
Simmons, J A, Blount, M A, Moon, J S, Lyo, S K, Baca, W E, Wendt, J R, Reno, J L, and Hafich, M J. 1998. "Planar quantum transistor based on 2D{endash}2D tunneling in double quantum well heterostructures". United States. https://doi.org/10.1063/1.368610.
@article{osti_663679,
title = {Planar quantum transistor based on 2D{endash}2D tunneling in double quantum well heterostructures},
author = {Simmons, J A and Blount, M A and Moon, J S and Lyo, S K and Baca, W E and Wendt, J R and Reno, J L and Hafich, M J},
abstractNote = {We report on our work on the double electron layer tunneling transistor (DELTT), based on the gate control of two-dimensional{endash}two-dimensional (2D{endash}2D) tunneling in a double quantum well heterostructure. While previous quantum transistors have typically required tiny laterally defined features, by contrast the DELTT is entirely planar and can be reliably fabricated in large numbers. We use a novel epoxy-bond-and-stop-etch flip-chip process, whereby submicron gating on opposite sides of semiconductor epitaxial layers as thin as 0.24 {mu}m can be achieved. Because both electron layers in the DELTT are 2D, the resonant tunneling features are unusually sharp, and can be easily modulated with one or more surface gates. We demonstrate DELTTs with peak-to-valley ratios in the source-drain I{endash}V curve of order 20:1 below 1 K. Both the height and position of the resonant current peak can be controlled by gate voltage over a wide range. DELTTs with larger subband energy offsets ({approximately}21 meV) exhibit characteristics that are nearly as good at 77 K, in good agreement with our theoretical calculations. Using these devices, we also demonstrate bistable memories operating at 77 K. Finally, we briefly discuss the prospects for room temperature operation, increases in gain and high speed. {copyright} {ital 1998 American Institute of Physics.}},
doi = {10.1063/1.368610},
url = {https://www.osti.gov/biblio/663679}, journal = {Journal of Applied Physics},
number = 10,
volume = 84,
place = {United States},
year = {Sun Nov 01 00:00:00 EST 1998},
month = {Sun Nov 01 00:00:00 EST 1998}
}