Phases of itinerant anyons in Laughlin's quantum Hall states on a lattice
preprint, arXiv:2603.22389
Abstract:
We study phases of itinerant anyons when hole-doping Laughlin-like states in fractional Chern insulators (FCIs). In light of the recent observation of time-reversal-broken superconductivity near FCIs in van der Waals materials, a theoetical understanding of doped fractional quantum Hall states on a lattice has been developed by Shi and Senthil [Phys. Rev. X 15, 031069], reviving old ideas about "anyon superconductivity". We test these ideas analytically within an effective parton mean-field theory and numerically with variational Monte Carlo, pointing out that the predicted state depends on whether the Laughlin order at ν=1/m is described by a U(1), or an SU(m) Chern-Simons field, the latter implying a symmetry between the m parton species. Our results demonstrate that the interplay between band Berry curvature and effective anyon dispersion has crucial implications for which anyonic phase is realized. In the expermentally relevant scenario of hole-doping the ν=1/3 fermionic FCI, our results uncover a mechanism for the formation of an anyon superconducting state of half-integer central charge in the case when the energetically cheapest excitations are the fundamental 1/3 charge anyons, bypassing the need for these anyons to pair into charge-2/3 composites, which has generally been assumed in similar anyon superconductivity constructions.
Partition function of the Kitaev quantum double model
Physical Review B American Physical Society (APS) (2026)
Paired Parton Trial States for the Superfluid-Fractional Chern Insulator Transition
(2026)
Linear response and exact hydrodynamic projections in Lindblad equations with decoupled Bogoliubov hierarchies
SciPost Physics Stichting SciPost 20:2 (2026) 058