Topological transition on the conformal manifold

Despite great successes in the study of gapped phases, a comprehensive understanding of the gapless phases and their transitions is still under development. In this paper, we study a general phenomenon in the space of (1+1)-dimensional critical phases with fermionic degrees of freedom described by a...

Full description

Saved in:
Bibliographic Details
Published in:Physical review research 2020-08, Vol.2 (3), p.033317, Article 033317
Main Authors: Ji, Wenjie, Shao, Shu-Heng, Wen, Xiao-Gang
Format: Article
Language:English
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Despite great successes in the study of gapped phases, a comprehensive understanding of the gapless phases and their transitions is still under development. In this paper, we study a general phenomenon in the space of (1+1)-dimensional critical phases with fermionic degrees of freedom described by a continuous family of conformal field theories (CFTs), also known as the conformal manifold. Along a one-dimensional locus on the conformal manifold, there can be a transition point, across which the fermionic CFTs on the two sides differ by stacking an invertible fermionic topological order (IFTO), point by point along the locus. At every point on the conformal manifold, the order and disorder operators have power-law two-point functions, but their critical exponents cross over with each other at the transition point, where stacking the IFTO leaves the fermionic CFT unchanged. We call this continuous transition on the fermionic conformal manifold a topological transition. By gauging the fermion parity, the IFTO stacking becomes a Kramers-Wannier duality between the corresponding bosonic CFTs. Both the IFTO stacking and the Kramers-Wannier duality are induced by the electromagnetic duality of the (2+1)-dimensionalZ_{2} topological order. We provide several examples of topological transitions, including the familiar Luttinger model of spinless fermions (i.e., the c=1 massless Dirac fermion with the Thirring interaction) and a class of c=2 examples describing U(1)×SU(2)-protected gapless phases.
ISSN:2643-1564
2643-1564
DOI:10.1103/PhysRevResearch.2.033317