Anisotropy-induced collapse of Landau levels in Weyl semimetals and its detection via the planar Hall effect

Abstract: The planar Hall effect (PHE) is a powerful tool for characterizing Weyl semimetals (WSMs). Here, we inves- tigate the PHE in general anisotropic WSMs under strong magnetic fields. We analytically derive the Landau levels (LLs) and their wavefunctions using the Bogoliubov transformation, where the tilt vector, anisotropic axis of the Fermi velocity, and the magnetic field can be oriented in arbitrary directions. Notably, due to the interaction with the magnetic field and the anisotropy of the Fermi velocity, the component of the tilt vector perpendicular to the magnetic field can induce a tilt in the LLs parallel to the magnetic field. Our analytical re- sults show that the LLs do not collapse in type-I WSMs but must collapse in type-II WSMs when the magnetic field is vertical to the tilt vector. More importantly, we demonstrate that the magnetotransport signal of the LL collapse, which manifests as significant enhancement and quantum oscillations in the longitudinal and planar Hall conductivities simultaneously, can be used to identify the phase transition from type-I to type-II WSMs.