On the Thermal Transport Puzzles in $\alpha\mbox{-}\mathrm{RuCl}_3$

Thermal transport has been used to probe the nature of $\alpha\mbox{-}\mathrm{RuCl}_3$, an important candidate of Kitaev material. Two remarkable observations were made under applied magnetic fields at low temperatures, and have stimulated extensive discussions. One is a sizable thermal Hall effect, and the other is an apparent "oscillation" of the longitudinal thermal conductivity with the magnetic field. It has been proposed that the former is due to a bosonic Chern band. Meanwhile, the origin of the latter has largely remained obscure. This work aims to resolve this "oscillation" puzzle. By examining the thermal transport data as well as other measured properties of $\alpha\mbox{-}\mathrm{RuCl}_3$, we argue that the most plausible scenario is that of phonons scattering with spin degrees of freedom across multiple phases. We substantiate this picture into a phenomenological theory, which reproduces the "oscillation" behavior in a simple manner and makes predictions that can be examined by future experiments. Moreover, our phenomenological theory and the aforementioned proposal for the thermal Hall effect support each other. We hope this work can thus help settle the physical mechanism behind the thermal transport puzzles in $\alpha\mbox{-}\mathrm{RuCl}_3$.