Electronic band structure reconstruction in NixZrTe2

Abstract

The filling of the large van der Waals gap in Transition Metal Dichalcogenides (TMDs) often leads to lattice and electronic instabilities, which prelude the onset of a rich phenomenology. Here, we investigate the electronic structure of the TMDs ZrTe2 and Ni-intercalated ZrTe2 (NixZrTe2, x≈ 0.05) employing angle-resolved photoemission spectroscopy (ARPES). We readily identify in NixZrTe2 two flat bands, most likely associated with localized Ni-derived 3d-states, at about ≈-0.7 eV and ≈-1.2 eV in binding energy. The presence of these flat bands is observed for all temperatures (T) in our study. More significantly, at low-T, we identify an electronic structure reconstruction in NixZrTe2, which halves the electronic periodicity along the kz direction. This is reminiscent of a commensurate band folding with wave-vector q=(0,0,π). Together with previous results from macroscopic measurements, namely heat capacity and resistivity, our findings suggest that Ni intercalation drives a structural instability at T*=287 K, which causes the observed electronic band reconstruction. Our findings invite further investigation into the structural properties of ZrTe2 and of the intercalated and defect-engineered versions of this material.