The thermal Hall effect has been proposed as a powerful tool to probe exotic topological excitations in quantum spin liquids, with the spectacular report of a half-quantized thermal Hall effect in the Kitaev material α-RuCl3 [1,2]. These results hold much promise for quantum computing.
However, it is becoming surprisingly apparent that phonons can also produce a large thermal Hall effect across a wide range of quantum materials, from cuprate superconductors [3,4] to the titanates [5] and frustrated magnets [6]. A significant phonon Hall effect is also suspected in α-RuCl3 [7, 8]. While phonons carry no charge and are common low energy excitations in solids, the origin of the handedness that gives rise to a phonon Hall effect in a magnetic field remains an enigma. Besides, the present ubiquity of the phonon Hall effect calls for caution when interpreting the results of quantum spin liquids candidates.
During the talk, I will share the signatures of the thermal Hall effect of phonons and how we came to discover it; why this is interesting, and how we can learn about quantum materials through this journey of serendipitous discoveries. By the end of the presentation, I hope to convince you that the thermal Hall effect is a technique that needs to be more fully/carefully exploited experimentally and the phonon Hall effect a property that needs to be better understood theoretically.
References
[1] Kasahara et al., Nature 559, 277 (2018)
[2] Yokoi et al., Science 373, 6554 (2021)
[3] Grissonnanche et al., Nature 571, 376 (2019)
[4] Grissonnanche et al., Nat. Phys. 16, 1108 (2020)
[5] Li et al., PRL 105, 225901 (2020)
[6] Hirokane et al. PRB 99, 134419 (2019)
[7] Hentrich et al. PRB 99, 085136 (2019)
[8] Lefrançois et al. PRX 12, 0021025 (2022)