Observation of quasi-two-dimensional Dirac fermions in ZrTe5

TL;DR

This paper reports the discovery of quasi-two-dimensional Dirac fermions in ZrTe5 using magneto-optics and transport measurements, revealing its unique electronic structure and topological properties.

Contribution

It provides the first comprehensive experimental evidence of Dirac fermions in ZrTe5 through magneto-optics and transport, highlighting its quasi-2D nature and topological phase.

Findings

Square-root-B dependence of inter-Landau-level resonance

Observation of non-trivial Berry phase in SdH oscillations

Detection of bulk quantum Hall plateaus

Abstract

Since the discovery of graphene, layered materials have attracted extensive interests owing to their unique electronic and optical characteristics. Among them, Dirac semimetal, one of the most appealing categories, has been a long-sought objective in layered systems beyond graphene. Recently, layered pentatelluride ZrTe5 was found to host signatures of Dirac semimetal. However, the low Fermi level in ZrTe5 strongly hinders a comprehensive understanding of the whole picture of electronic states through photoemission measurements, especially in the conduction band. Here, we report the observation of Dirac fermions in ZrTe5 through magneto-optics and magneto-transport. By applying magnetic field, we observe a square-root-B dependence of inter-Landau-level resonance and Shubnikov-de Haas (SdH) oscillations with non-trivial Berry phase, both of which are hallmarks of Dirac fermions. The angular-dependent SdH oscillations show a clear quasi-two-dimensional feature with highly anisotropic Fermi surface and band topology, in stark contrast to the 3D Dirac semimetal such as Cd3As2. This is further confirmed by the angle-dependent Berry phase measurements and the observation of bulk quantum Hall plateaus. The unique band dispersion is theoretically understood: the system is at the critical point between a 3D Dirac semimetal and a topological insulator phase. With the confined interlayer dispersion and reducible dimensionality, our work establishes ZrTe5 as an ideal platform for exploring exotic physical phenomena of Dirac fermions.