Chiral Landau levels in Weyl semimetal NbAs with multiple topological carriers

Xiang Yuan,Xiaolong Chen,Zhengcai Xia,Mengyao Zhang,Zhong Wang,Xiaoxing Zhang,Chunhua Feng ,Minhao Zhao,Weiyi Wang,Zhongbo Yan,Hugen Yan,Zehao Lin,Jiaxiang Wang,Zhilin Li,Dmitry Smirnov,Cui Shang,Chaoyu Song,Cheng Zhang,Jonathan Ludwig,Tian Xie,Yuxuan Jiang,Zefang Ye,Yanwen Liu,Faxian Xiu

doi:10.1038/s41467-018-04080-4

Abstract

Recently, Weyl semimetals have been experimentally discovered in both inversion-symmetry-breaking and time-reversal-symmetry-breaking crystals. The non-trivial topology in Weyl semimetals can manifest itself with exotic phenomena, which have been extensively investigated by photoemission and transport measurements. Despite the numerous experimental efforts on Fermi arcs and chiral anomaly, the existence of unconventional zeroth Landau levels, as a unique hallmark of Weyl fermions, which is highly related to chiral anomaly, remains elusive owing to the stringent experimental requirements. Here, we report the magneto-optical study of Landau quantization in Weyl semimetal NbAs. High magnetic fields drive the system toward the quantum limit, which leads to the observation of zeroth chiral Landau levels in two inequivalent Weyl nodes. As compared to other Landau levels, the zeroth chiral Landau level exhibits a distinct linear dispersion in magnetic field direction and allows the optical transitions without the limitation of zero z momentum or sqrt B magnetic field evolution. The magnetic field dependence of the zeroth Landau levels further verifies the predicted particle-hole asymmetry of the Weyl cones. Meanwhile, the optical transitions from the normal Landau levels exhibit the coexistence of multiple carriers including an unexpected massive Dirac fermion, pointing to a more complex topological nature in inversion-symmetry-breaking Weyl semimetals. Our results provide insights into the Landau quantization of Weyl fermions and demonstrate an effective tool for studying complex topological systems.

Highlights

Weyl semimetals have been experimentally discovered in both inversionsymmetry-breaking and time-reversal-symmetry-breaking crystals
Besides the Fermi arcs and chiral anomaly, one of the most important features of Weyl semimetals is the presence of the zeroth chiral Landau level, which is linearly dispersed in Kz direction[27,28,29]
Corroborated with our theory, five kinds of optical transitions involving the chiral and conventional Landau levels are unambiguously distinguished, which construct the whole band structure of NbAs under magnetic field as summarized in the end. Besides these two inequivalent Weyl nodes, we reveal the coexistence of massive Dirac fermions, as well as trivial band insulating state, suggesting a more complex topological nature in the Weyl semimetal family

Summary

Introduction

Weyl semimetals have been experimentally discovered in both inversionsymmetry-breaking and time-reversal-symmetry-breaking crystals. We report the magneto-optical study of Landau quantization in Weyl semimetal NbAs. High magnetic fields drive the system toward the quantum limit, which leads to the observation of zeroth chiral Landau levels in two inequivalent Weyl nodes. It was theoretically predicted to be a hallmark of Weyl fermions that leads to the widely observed chiral anomaly in Weyl semimetals[16,17,18,19,20,21,22,24] Directly detecting this distinct zeroth Landau level through conventional photoemission or transport experiments remains an unprecedented challenge since both magnetic field and Landau level spectroscopy are required[27]. Two sets of inequivalent Wpeffiyffiffil velocity were identified through B coneps ffiwffiffi ith different and n dependence

Methods

Results

Conclusion