Photoemission Spectroscopic Evidence for the Dirac Nodal Line in Monoclinic Semimetal SrAs3

Abstract

Topological nodal-line semimetals with exotic quantum properties are characterized by symmetry-protected line-contact bulk band crossings in the momentum space. However, in most of identified topological nodal-line compounds, these topological non-trivial nodal lines are enclosed by complicated topological trivial states at the Fermi energy (EF), which would perplex their identification and hinder further applications. Utilizing angle-resolved photoemission spectroscopy and first-principles calculations, we provide compelling evidence for the existence of Dirac nodal-line fermions in the monoclinic semimetal SrAs3, which are close to EF and away from distraction of complex trivial Fermi surfaces or surface states. Our calculation indicates that two bands with opposite parity are inverted around Y near EF, which results in the single nodal loop at the -Y-S plane with a negligible spin-orbit coupling effect. We track these band crossings and then unambiguously identify the complete nodal loop quantitatively, which provides a critical experimental support to the prediction of nodal-line fermions in the CaP3 family of materials. Hosting simple topological non-trivial bulk electronic states around EF and no interfering with surface states on the natural cleavage plane, SrAs3 is expected to be a potential platform for topological quantum state investigation and applications.