Composite helical edges from Abelian fractional topological insulators

Abstract

We study an interacting composite (1+1/n) Abelian helical edge state made of a regular helical liquid carrying charge e and a (fractionalized) helical liquid carrying charge e/n. A systematic framework is developed for these composite (1+1/n) Abelian helical edge states with n=1,2,3. For n=2, the composite edge state consists of a regular helical Luttinger liquid and a fractional topological insulator (the Abelian Z4 topological order) edge state arising from half-filled conjugated Chern bands. The composite edge state with n=2 is pertinent to the recent twisted MoTe2 experiment, suggesting a possible fractional topological insulator with conductance 32e2h per edge. Using bosonization, we construct generic phase diagrams in the presence of weak Rashba spin-orbit coupling. In addition to a phase of free bosons, we find a time-reversal symmetry-breaking localized insulator, two perfect positive drag phases, a perfect negative drag phase (for n=2,3), a time-reversal symmetric Anderson localization (only for n=1), and a disorder-dominated metallic phase analogous to the =2/3 disordered fractional quantum Hall edges (only for n=3). We further compute the two-terminal edge-state conductance, the primary experimental characterization for the (fractional) topological insulator. Remarkably, the negative drag phase gives rise to an unusual edge-state conductance, (1-1/n)e2h, not directly associated with the filling factor. We further investigate the effect of an applied in-plane magnetic field. For n>1, the applied magnetic field can result in a phase with edge-state conductance 1ne2h, providing another testable signature. Our work establishes a systematic understanding of the composite (1+1/n) Abelian helical edge, paving the way for future experimental and theoretical studies.