Hamiltonian Description of Composite Fermions: Magnetoexciton
  Dispersions

A. Lopez; A. Lopez; A. Lopez; A. Lopez; A. Lopez; A.H. MacDonald; A.H. MacDonald; A.L. Fetter; A.L. Fetter; B.I. Halperin; B.I. Halperin; B.I. Halperin; B.I. Halperin; C. Kallin; C. Timm; D. Bohm; D. Levesque; D. Tsui; D. Yoshioka; D.-H. Lee; D.H. Lee; D.P. Arovas; F.C. Zhang; F.D.M. Haldane; F.D.M. Haldane; F.F. Fang; G. Baym; G. Dev; G. Murthy; G. Murthy; G. Murthy; G. Murthy; G. Rickayzen; Ganpathy Murthy; H.A. Fertig; H.C.A. Oji; H.L. Stormer; I.K. Marmorkos; I.V. Lerner; J.K. Jain; J.K. Jain; J.K. Jain; J.M. Leinaas; J.P. Longo; K. Moon; K. Park; K. Park; K. Yang; K.W. Chiu; M. Kasner; M.J. Manfra; M.W. Ortalano; N. d’Ambrumenil; N. Horing; N. Read; N. Read; N. Read; N. Read; N. Read; P. Hawrylak; P.K. Lam; P.M. Platzman; Q. Dai; R. Morf; R. Price; R. Shankar; R. Tycko; R.B. Laughlin; R.B. Laughlin; R.K. Kamilla; R.K. Kamilla; R.K. Kamilla; R.R. Du; R.R. Du; S. He; S. He; S. He; S. M. Girvin; S.-C. Zhang; S.-C. Zhang; S.E. Barrett; S.H. Simon; S.H. Simon; S.H. Simon; S.H. Simon; S.L. Sondhi; S.M. Girvin; S.M. Girvin; S.M. Grivin; S.S. Mandal; T. Ando; T. Chakraborty; T. Nakajima; T. Theis; V. Kalmeyer; V. Melik-Alaverdian; V. Melik-Alaverdian; V. Pasquier; W. Kohn; X.C. Xie; X.G. Wu; Yu.A. Bychkov

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Hamiltonian Description of Composite Fermions: Magnetoexciton Dispersions

Authors: A. Lopez
A. Lopez
A. Lopez
A. Lopez
A. Lopez
A.H. MacDonald
A.H. MacDonald
A.L. Fetter
A.L. Fetter
B.I. Halperin
B.I. Halperin
B.I. Halperin
B.I. Halperin
C. Kallin
C. Timm
D. Bohm
D. Levesque
D. Tsui
D. Yoshioka
D.-H. Lee
D.H. Lee
D.P. Arovas
F.C. Zhang
F.D.M. Haldane
F.D.M. Haldane
F.F. Fang
G. Baym
G. Dev
G. Murthy
G. Murthy
G. Murthy
G. Murthy
G. Rickayzen
Ganpathy Murthy
H.A. Fertig
H.C.A. Oji
H.L. Stormer
I.K. Marmorkos
I.V. Lerner
J.K. Jain
J.K. Jain
J.K. Jain
J.M. Leinaas
J.P. Longo
K. Moon
K. Park
K. Park
K. Yang
K.W. Chiu
M. Kasner
M.J. Manfra
M.W. Ortalano
N. d’Ambrumenil
N. Horing
N. Read
N. Read
N. Read
N. Read
N. Read
P. Hawrylak
P.K. Lam
P.M. Platzman
Q. Dai
R. Morf
R. Price
R. Shankar
R. Tycko
R.B. Laughlin
R.B. Laughlin
R.K. Kamilla
R.K. Kamilla
R.K. Kamilla
R.R. Du
R.R. Du
S. He
S. He
S. He
S. M. Girvin
S.-C. Zhang
S.-C. Zhang
S.E. Barrett
S.H. Simon
S.H. Simon
S.H. Simon
S.H. Simon
S.L. Sondhi
S.M. Girvin
S.M. Girvin
S.M. Grivin
S.S. Mandal
T. Ando
T. Chakraborty
T. Nakajima
T. Theis
V. Kalmeyer
V. Melik-Alaverdian
V. Melik-Alaverdian
V. Pasquier
W. Kohn
X.C. Xie
X.G. Wu
Yu.A. Bychkov
Publication date: 11 March 1999
Publisher: 'American Physical Society (APS)'
Doi

Abstract

A microscopic Hamiltonian theory of the FQHE, developed by Shankar and myself based on the fermionic Chern-Simons approach, has recently been quite successful in calculating gaps in Fractional Quantum Hall states, and in predicting approximate scaling relations between the gaps of different fractions. I now apply this formalism towards computing magnetoexciton dispersions (including spin-flip dispersions) in the

\nu=1/3

, 2/5, and 3/7 gapped fractions, and find approximate agreement with numerical results. I also analyse the evolution of these dispersions with increasing sample thickness, modelled by a potential soft at high momenta. New results are obtained for instabilities as a function of thickness for 2/5 and 3/7, and it is shown that the spin-polarized 2/5 state, in contrast to the spin-polarized 1/3 state, cannot be described as a simple quantum ferromagnet.Comment: 18 pages, 18 encapsulated ps figure

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