Temperature dependence of current self-oscillations and electric field
  domains in sequential tunneling doped superlattices

A. Wacker; A. Wacker; A.M. Tomlinson; B. Laikhtman; B. Sun; C.Y. Li; D. Sánchez; David Sánchez; G. Platero; H. Steuer; H.T. Grahn; J. Kastrup; J. Kastrup; J.N. Wang; K.K. Choi; L. L. Bonilla; L.G. Mourokh; L.L. Bonilla; L.L. Bonilla; L.L. Bonilla; M. Moscoso; N. Ohtani; N. Ohtani; O.M. Bulashenko; R. Aguado; X.R. Wang; X.R. Wang; Y. Kuramoto; Y. Kuramoto; Y. Xu; Y. Zhang

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Temperature dependence of current self-oscillations and electric field domains in sequential tunneling doped superlattices

Authors: A. Wacker
A. Wacker
A.M. Tomlinson
B. Laikhtman
B. Sun
C.Y. Li
D. Sánchez
David Sánchez
G. Platero
H. Steuer
H.T. Grahn
J. Kastrup
J. Kastrup
J.N. Wang
K.K. Choi
L. L. Bonilla
L.G. Mourokh
L.L. Bonilla
L.L. Bonilla
L.L. Bonilla
M. Moscoso
N. Ohtani
N. Ohtani
O.M. Bulashenko
R. Aguado
X.R. Wang
X.R. Wang
Y. Kuramoto
Y. Kuramoto
Y. Xu
Y. Zhang
Publication date: 6 April 2001
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We examine how the current--voltage characteristics of a doped weakly coupled superlattice depends on temperature. The drift velocity of a discrete drift model of sequential tunneling in a doped GaAs/AlAs superlattice is calculated as a function of temperature. Numerical simulations and theoretical arguments show that increasing temperature favors the appearance of current self-oscillations at the expense of static electric field domain formation. Our findings agree with available experimental evidence.Comment: 7 pages, 5 figure

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