Generation of chirality and orbital magnetization by Stone-Wales-type lattice defects in the Kitaev spin liquid

Abstract

In this work we extend our study of the effect of certain crystallographic defects on the spin-1/2 Kitaev honeycomb spin liquid (arXiv:2511.19409), focusing on its gapless phase and contrasting with the gapped phase. We identify a Stone-Wales (SW) local defect consisting of a 90 bond rotation that preserves Kitaev bond labels for edge-sharing octahedra and thereby enables exact solvability. These SW-type defects involve odd-sided plaquettes with π/2 fluxes, but can be created locally. An isolated defect hosts a time-reversal pair of ground-state flux configurations with large net chirality. Certain excitations are also chiral. The chirality manifests in Majorana local Chern marker and in scalar spin chirality, producing electronic orbital magnetization. T-matrix analysis and numerics at finite defect density nd show that defect chiralities generate a topological gap of 11 nd protecting a Chern number C= 1. Emergent ferromagnetic long range Ising interactions r-γ with 2<γ < 3 between defect chiralities lead to a finite temperature Tc phase transition into the chiral spin liquid. The Tc is proportional to nd and diverges when γ→ 2. We also consider additional solvable impurity potentials and find that γ can be reduced to below 2.3 and correspondingly enhance Tc. Our results offer applications to 2D Dirac cone systems with a finite density of fluctuating Ising magnetic impurities and to identifying spin liquids with lattice defects.

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