Classification and analysis of two-dimensional Abelian fractional topological insulators

Michael Levin; Ady Stern

doi:10.1103/PhysRevB.86.115131

Classification and analysis of two-dimensional Abelian fractional topological insulators

Michael Levin, Ady Stern

Department of Condensed Matter Physics

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

We present a general framework for analyzing fractionalized, time-reversal invariant electronic insulators in two dimensions. The framework applies to all insulators whose quasiparticles have Abelian braiding statistics. First, we construct the most general Chern-Simons theories that can describe these states. We then derive a criterion for when these systems have protected gapless edge modes, that is, edge modes that cannot be gapped out without breaking time-reversal or charge-conservation symmetry. The systems with protected edge modes can be regarded as fractionalized analogues of topological insulators. We show that previous examples of 2D fractional topological insulators are special cases of this general construction. As part of our derivation, we define the concept of "local Kramers degeneracy" and prove a local version of Kramers theorem.

Original language	English
Article number	115131
Journal	Physical Review B
Volume	86
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevB.86.115131
State	Published - 21 Sep 2012

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.86.115131

http://arxiv.org/pdf/1205.1244License: Unspecified

Cite this

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title = "Classification and analysis of two-dimensional Abelian fractional topological insulators",

abstract = "We present a general framework for analyzing fractionalized, time-reversal invariant electronic insulators in two dimensions. The framework applies to all insulators whose quasiparticles have Abelian braiding statistics. First, we construct the most general Chern-Simons theories that can describe these states. We then derive a criterion for when these systems have protected gapless edge modes, that is, edge modes that cannot be gapped out without breaking time-reversal or charge-conservation symmetry. The systems with protected edge modes can be regarded as fractionalized analogues of topological insulators. We show that previous examples of 2D fractional topological insulators are special cases of this general construction. As part of our derivation, we define the concept of {"}local Kramers degeneracy{"} and prove a local version of Kramers theorem.",

author = "Michael Levin and Ady Stern",

note = "Alfred P. Sloan Research Fellowship; US-Israel Binational Science Foundation; Minerva foundation; Microsoft Station QM.L. was supported in part by an Alfred P. Sloan Research Fellowship. A. S. thanks the US-Israel Binational Science Foundation, the Minerva foundation and Microsoft Station Q for financial support.",

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AU - Stern, Ady

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N2 - We present a general framework for analyzing fractionalized, time-reversal invariant electronic insulators in two dimensions. The framework applies to all insulators whose quasiparticles have Abelian braiding statistics. First, we construct the most general Chern-Simons theories that can describe these states. We then derive a criterion for when these systems have protected gapless edge modes, that is, edge modes that cannot be gapped out without breaking time-reversal or charge-conservation symmetry. The systems with protected edge modes can be regarded as fractionalized analogues of topological insulators. We show that previous examples of 2D fractional topological insulators are special cases of this general construction. As part of our derivation, we define the concept of "local Kramers degeneracy" and prove a local version of Kramers theorem.

AB - We present a general framework for analyzing fractionalized, time-reversal invariant electronic insulators in two dimensions. The framework applies to all insulators whose quasiparticles have Abelian braiding statistics. First, we construct the most general Chern-Simons theories that can describe these states. We then derive a criterion for when these systems have protected gapless edge modes, that is, edge modes that cannot be gapped out without breaking time-reversal or charge-conservation symmetry. The systems with protected edge modes can be regarded as fractionalized analogues of topological insulators. We show that previous examples of 2D fractional topological insulators are special cases of this general construction. As part of our derivation, we define the concept of "local Kramers degeneracy" and prove a local version of Kramers theorem.

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Classification and analysis of two-dimensional Abelian fractional topological insulators

Abstract

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