Pretopological fractional excitations in the two-leg flux ladder

Marcello Calvanese Strinati, Sharmistha Sahoo, Kirill Shtengel, Eran Sela

Research output: Contribution to journalArticlepeer-review

24 Scopus citations

Abstract

Topological order, the hallmark of fractional quantum Hall states, is primarily defined in terms of ground-state degeneracy on higher-genus manifolds, e.g., the torus. We investigate analytically and numerically the smooth crossover between this topological regime and the Tao-Thouless thin torus quasi-one-dimensional (1D) limit. Using the wire-construction approach, we analyze an emergent charge density wave (CDW) signifying the breakdown of topological order, and relate its phase shifts to Wilson loop operators. The CDW amplitude decreases exponentially with the torus circumference once it exceeds the transverse correlation length controllable by the interwire coupling. By means of numerical simulations based on the matrix product states (MPS) formalism, we explore the extreme quasi-1D limit in a two-leg flux ladder and present a simple recipe for probing fractional charge excitations in the ν=1/2 Laughlin-like state of hard-core bosons. We discuss the possibility of realizing this construction in cold-atom experiments. We also address the implications of our findings to the possibility of producing non-Abelian zero modes. As known from rigorous no-go theorems, topological protection for exotic zero modes such as parafermions cannot exist in 1D fermionic systems and the associated degeneracy cannot be robust. Our theory of the 1D-2D crossover allows us to calculate the splitting of the degeneracy, which vanishes exponentially with the number of wires, similarly to the CDW amplitude.

Original languageEnglish
Article number245101
JournalPhysical Review B
Volume99
Issue number24
DOIs
StatePublished - 3 Jun 2019

Bibliographical note

Publisher Copyright:
© 2019 American Physical Society.

Funding

We thank M. Burrello, E. G. D. Torre, L. Mazza, G. Pagano, E. Shimshoni, and L. Silberman for fruitful discussions. We are grateful to R. Berkovits and D. Rossini for support. E.S. and K.S. were supported by the U.S.-Israel Binational Science Foundation (Grant No. 2016255). M.C.S. acknowledges support from the Israel Science Foundations, Grants No. 231/14 and No. 1452/14. S.S. acknowledges support from NSERC.

FundersFunder number
Israel Science Foundations231/14, 1452/14
U.S.-Israel Binational Science Foundation2016255
Natural Sciences and Engineering Research Council of Canada

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