Composite fermion theory of excitations in the fractional quantum Hall effect

J. K. Jain, K. Park, M. R. Peterson, V. W. Scarola

Research output: Contribution to journalConference article

4 Citations (Scopus)

Abstract

Transport experiments are sensitive to charged 'quasiparticle' excitations of the fractional quantum Hall effect. Inelastic Raman scattering experiments have probed an amazing variety of other excitations: excitons, rotons, bi-rotons, trions, flavor altering excitons, spin waves, spin-flip excitons, and spin-flip rotons. This paper reviews the status of our theoretical understanding of these excitations.

Original languageEnglish (US)
Pages (from-to)602-609
Number of pages8
JournalSolid State Communications
Volume135
Issue number9-10
DOIs
StatePublished - Sep 1 2005
EventFundamental Optical and Quantum Effects in Condensed Matter -
Duration: Sep 9 2004Sep 10 2004

Fingerprint

Quantum Hall effect
rotons
Fermions
quantum Hall effect
Excitons
fermions
excitons
composite materials
Composite materials
excitation
Inelastic scattering
Spin waves
Flavors
magnons
Raman scattering
inelastic scattering
Experiments
Raman spectra
LDS 751

All Science Journal Classification (ASJC) codes

  • Chemistry(all)
  • Condensed Matter Physics
  • Materials Chemistry

Cite this

Jain, J. K. ; Park, K. ; Peterson, M. R. ; Scarola, V. W. / Composite fermion theory of excitations in the fractional quantum Hall effect. In: Solid State Communications. 2005 ; Vol. 135, No. 9-10. pp. 602-609.
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Composite fermion theory of excitations in the fractional quantum Hall effect. / Jain, J. K.; Park, K.; Peterson, M. R.; Scarola, V. W.

In: Solid State Communications, Vol. 135, No. 9-10, 01.09.2005, p. 602-609.

Research output: Contribution to journalConference article

TY - JOUR

T1 - Composite fermion theory of excitations in the fractional quantum Hall effect

AU - Jain, J. K.

AU - Park, K.

AU - Peterson, M. R.

AU - Scarola, V. W.

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N2 - Transport experiments are sensitive to charged 'quasiparticle' excitations of the fractional quantum Hall effect. Inelastic Raman scattering experiments have probed an amazing variety of other excitations: excitons, rotons, bi-rotons, trions, flavor altering excitons, spin waves, spin-flip excitons, and spin-flip rotons. This paper reviews the status of our theoretical understanding of these excitations.

AB - Transport experiments are sensitive to charged 'quasiparticle' excitations of the fractional quantum Hall effect. Inelastic Raman scattering experiments have probed an amazing variety of other excitations: excitons, rotons, bi-rotons, trions, flavor altering excitons, spin waves, spin-flip excitons, and spin-flip rotons. This paper reviews the status of our theoretical understanding of these excitations.

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JF - Solid State Communications

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