Fate of interaction-driven topological insulators under disorder

Jing Wang; Carmine Ortix; Jeroen van den Brink; Dmitry V. Efremov

doi:10.1103/PhysRevB.96.201104

Fate of interaction-driven topological insulators under disorder

Jing Wang^*, Carmine Ortix, Jeroen van den Brink, Dmitry V. Efremov

^*Corresponding author for this work

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

Abstract

We analyze the effect of disorder on the weak-coupling instabilities of a quadratic band crossing point (QBCP) in two-dimensional Fermi systems, which, in the clean limit, display interaction-driven topological insulating phases. In the framework of a renormalization group procedure, which treats fermionic interactions and disorder on the same footing, we test all possible instabilities and identify the corresponding ordered phases in the presence of disorder for both single-valley and two-valley QBCP systems. We find that disorder generally suppresses the critical temperature at which the interaction-driven topologically nontrivial order sets in. Strong disorder can also drive a topological phase transition into a topologically trivial insulating state.

Original language	English
Article number	201104
Number of pages	6
Journal	Physical Review B-Condensed Matter
Volume	96
Issue number	20
DOIs	https://doi.org/10.1103/PhysRevB.96.201104
Publication status	Published - 8 Dec 2017

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title = "Fate of interaction-driven topological insulators under disorder",

abstract = "We analyze the effect of disorder on the weak-coupling instabilities of a quadratic band crossing point (QBCP) in two-dimensional Fermi systems, which, in the clean limit, display interaction-driven topological insulating phases. In the framework of a renormalization group procedure, which treats fermionic interactions and disorder on the same footing, we test all possible instabilities and identify the corresponding ordered phases in the presence of disorder for both single-valley and two-valley QBCP systems. We find that disorder generally suppresses the critical temperature at which the interaction-driven topologically nontrivial order sets in. Strong disorder can also drive a topological phase transition into a topologically trivial insulating state.",

author = "Jing Wang and Carmine Ortix and Brink, {Jeroen van den} and Efremov, {Dmitry V.}",

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AU - Efremov, Dmitry V.

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N2 - We analyze the effect of disorder on the weak-coupling instabilities of a quadratic band crossing point (QBCP) in two-dimensional Fermi systems, which, in the clean limit, display interaction-driven topological insulating phases. In the framework of a renormalization group procedure, which treats fermionic interactions and disorder on the same footing, we test all possible instabilities and identify the corresponding ordered phases in the presence of disorder for both single-valley and two-valley QBCP systems. We find that disorder generally suppresses the critical temperature at which the interaction-driven topologically nontrivial order sets in. Strong disorder can also drive a topological phase transition into a topologically trivial insulating state.

AB - We analyze the effect of disorder on the weak-coupling instabilities of a quadratic band crossing point (QBCP) in two-dimensional Fermi systems, which, in the clean limit, display interaction-driven topological insulating phases. In the framework of a renormalization group procedure, which treats fermionic interactions and disorder on the same footing, we test all possible instabilities and identify the corresponding ordered phases in the presence of disorder for both single-valley and two-valley QBCP systems. We find that disorder generally suppresses the critical temperature at which the interaction-driven topologically nontrivial order sets in. Strong disorder can also drive a topological phase transition into a topologically trivial insulating state.

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Fate of interaction-driven topological insulators under disorder

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