Spin-Orbit Interaction Enhanced Fractional Quantum Hall States in the
  Second Landau Level

Averin D. V.; Chesi S.; d'Ambrumenil N.; Dresselhaus P. D.; Eisenstein J. P.; Fano G.; Greiter M.; Haldane F. D. M.; Haldane F. D. M.; Halperin B. I.; Kitaev A. Y.; Laughlin R. B.; Levin M.; Lommer G.; Luo J.; Moore G.; Morf R. H.; Morf R. H.; Nitta J.; Peterson M. R.; Rashba E. I.; Rezayi E.; Schliemann J.; Shibata N.; Shibata N.; Shibata N.; Storni M.; Tsui D. C.; Wang H.; White S. R.; Willet R.

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Spin-Orbit Interaction Enhanced Fractional Quantum Hall States in the Second Landau Level

Authors: Averin D. V.
Chesi S.
d'Ambrumenil N.
Dresselhaus P. D.
Eisenstein J. P.
Fano G.
Greiter M.
Haldane F. D. M.
Haldane F. D. M.
Halperin B. I.
Kitaev A. Y.
Laughlin R. B.
Levin M.
Lommer G.
Luo J.
Moore G.
Morf R. H.
Morf R. H.
Nitta J.
Peterson M. R.
Rashba E. I.
Rezayi E.
Schliemann J.
Shibata N.
Shibata N.
Shibata N.
Storni M.
Tsui D. C.
Wang H.
White S. R.
Willet R.
Publication date: 10 May 2010
Publisher: 'Japan Society of Applied Physics'
Doi

Abstract

We study the fractional quantum Hall effect at filling fractions 7/3 and 5/2 in the presence of the spin-orbit interaction, using the exact diagonalization method and the density matrix renormalization group (DMRG) method in a spherical geometry. Trial wave functions at these fillings are the Laughlin state and the Moore-Reed-Pfaffian state. The ground state excitation energy gaps and pair-correlation functions at fractional filling factor 7/3 and 5/2 in the second Landau level are calculated. We find that the spin-orbit interaction stabilizes the fractional quantum Hall states.Comment: 4pages, 4figure

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