Thierry Jolicoeur
Published 2025-01-30Version 1
The fractional quantum Hall effect (FQHE) realized in two-dimensional electron systems is explained by the emergent composite fermions (CF) out of ordinary electrons. It is possible to write down explicit wavefunctions explaining many if not all FQHE states. In bilayer systems there is a regime at integer filling of the lowest Landau level that displays a spontaneous breakdown of the U(1) relative phase between the two layers. This can be seen as interlayer phase coherence (ILC) in terms of electrons. Recent experiments in double layer samples of graphene have revealed the appearance of many FQHE states unique to the bilayer case. We discuss extensions of the CF idea in this situation as well as the possible existence of ILC of CFs.
Comments: 10 pages, talk given at the workshop "open questions in the quantum many-body problem" held in Institut Henri Poincare in Paris, July 2024, organized by Y. Castin and C. Sa de Melo. More beautiful version with fancy owl logo available at the journal website (open access)
Journal: Comptes Rendus. Physique, Volume 26 (2025), pp. 113-124
Hamiltonian Theory of the Fractional Quantum Hall Effect: Effect of Landau Level Mixing
Magneto-roton excitation of fractional quantum Hall effect: Comparison between theory and experiment
Composite fermions in the Fractional Quantum Hall Effect: Transport at finite wavevector
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