Quantization of the Thermal Hall Conductivity at Small Hall Angles

Mengxing Ye, Gábor B. Halász, Lucile Savary, Leon Balents

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Abstract

We consider the effect of coupling between phonons and a chiral Majorana edge in a gapped chiral spin liquid with Ising anyons (e.g., Kitaev's non-Abelian spin liquid on the honeycomb lattice). This is especially important in the regime in which the longitudinal bulk heat conductivity κxx due to phonons is much larger than the expected quantized thermal Hall conductance κxyq=(πT/12)(kB2/) of the ideal isolated edge mode, so that the thermal Hall angle, i.e., the angle between the thermal current and the temperature gradient, is small. By modeling the interaction between a Majorana edge and bulk phonons, we show that the exchange of energy between the two subsystems leads to a transverse component of the bulk current and thereby an effective Hall conductivity. Remarkably, the latter is equal to the quantized value when the edge and bulk can thermalize, which occurs for a Hall bar of length L, where is a thermalization length. We obtain ∼T-5 for a model of the Majorana-phonon coupling. We also find that the quality of the quantization depends on the means of measuring the temperature and, surprisingly, a more robust quantization is obtained when the lattice, not the spin, temperature is measured. We present general hydrodynamic equations for the system, detailed results for the temperature and current profiles, and an estimate for the coupling strength and its temperature dependence based on a microscopic model Hamiltonian. Our results may explain recent experiments observing a quantized thermal Hall conductivity in the regime of small Hall angle, κxy/κxx∼10-3, in α-RuCl3.

Original languageEnglish
Article number147201
JournalPhysical Review Letters
Volume121
Issue number14
DOIs
StatePublished - Oct 1 2018
Externally publishedYes

Funding

L. B. was supported by the DOE Office of Science’s Basic Energy Sciences program under Award No. DE-FG02- 08ER46524. M. Y. acknowledges support from the KITP graduate fellowship program under Grant No. NSF PHY-1748958 and the NSF DMR-1523036 from the University of Minnesota. G. B. H. is supported by the Gordon and Betty Moore Foundation’s EPiQS Initiative through Grant No. GBMF4304.

FundersFunder number
DOE Office of Science’s Basic Energy Sciences
National Science Foundation1523036, PHY-1748958, DMR-1523036
Gordon and Betty Moore Foundation
University of Minnesota

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