Abstract
We study the electronic structure of the nodal line semimetal ZrSiTe both experimentally and theoretically. We find two different surface states in ZrSiTe - topological drumhead surface states and trivial floating band surface states. Using the spectra of Wilson loops, we show that a non-trivial Berry phase that exists in a confined region within the Brillouin Zone gives rise to the topological drumhead-type surface states. The $\mathbb{Z}_2$ structure of the Berry phase induces a $\mathbb{Z}_2$ 'modular arithmetic' of the surface states, allowing surface states deriving from different nodal lines to hybridize and gap out, which can be probed by a set of Wilson loops. Our findings are confirmed by \textit{ab-initio} calculations and angle-resolved photoemission experiments, which are in excellent agreement with each other and the topological analysis. This is the first complete characterization of topological surface states in the family of square-net based nodal line semimetals and thus fundamentally increases the understanding of the topological nature of this growing class of topological semimetals.
Highlights
Band inversions in three-dimensional (3D) materials can lead to a variety of topological semimetals that can be distinguished by the dimensionality and connectivity of the band touching points [1,2,3,4,5]
We find two different surface states in ZrSiTe—topological drumhead surface states and trivial floating band surface states, which can be distinguished in angle-resolved photoemission spectroscopy (ARPES) experiments
Using the spectra of Wilson loops, we show that a nontrivial Berry phase that exists in a confined region within the Brillouin zone gives rise to the topological drumhead-type surface states
Summary
Band inversions in three-dimensional (3D) materials can lead to a variety of topological semimetals that can be distinguished by the dimensionality and connectivity of the band touching points [1,2,3,4,5]. If multiple nodal lines are present in one material, the band structure can be further characterized by their connectivity or linking structure; e.g., it is possible for nodal lines to form knotted nodal structures that are characterized by knot invariants [16,17,18] These band crossings often strongly influence the electronic properties of such topological semimetals [19]. While much attention has been directed towards the bulk properties of this class of materials, the topological drumhead surface states that are expected to derive from the presence of the nodal lines in the band structure have not been discussed in detail so far [46,47], and a general theoretical understanding is lacking. The nodal lines and Wilson loops were calculated with an inhouse code and the WannierTools [49] package
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