Tunneling into a two-dimensional electron system in a strong magnetic
  field

A. J. Tuberfeld; B. B. Goldberg; B. I. Halperin; B. I. Halperin; D. C. Langreth; E. H. Rezayi; G. D. Mahan; H. Buhman; J. P. Eisenstein; K.D. Schotte; P. M. Platzman; R. C. Ashoori; S. M. Girvin; Song He; W. K. Shung

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Tunneling into a two-dimensional electron system in a strong magnetic field

Authors: A. J. Tuberfeld
B. B. Goldberg
B. I. Halperin
B. I. Halperin
D. C. Langreth
E. H. Rezayi
G. D. Mahan
H. Buhman
J. P. Eisenstein
K.D. Schotte
P. M. Platzman
R. C. Ashoori
S. M. Girvin
Song He
W. K. Shung
Publication date: 8 June 1993
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We investigate the properties of the one-electron Green's function in an interacting two-dimensional electron system in a strong magnetic field, which describes an electron tunneling into such a system. From finite-size diagonalization, we find that its spectral weight is suppressed near zero energy, reaches a maximum at an energy of about

0.2e^{2}/\epsilon l_{c}

, and decays exponentially at higher energies. We propose a theoretical model to account for the low-energy behavior. For the case of Coulomb interactions between the electrons, at even-denominator filling factors such as

\nu=1/2

, we predict that the spectral weight varies as

e^{-\omega_0/|\omega|}

, for

\omega\rightarrow 0

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