Moir\'e induced electronic structure in monolayer V$_{2}$S$_{3}$ on Au(111).

There is immense interest in how the local environment influences the electronic structure of materials at the single layer limit. We characterize moir\'e induced spatial variations in the electronic structure of in-situ grown monolayer V$_{2}$S$_{3}$ on Au(111) by means of low temperature scanning tunneling microscopy and spectroscopy. We observe a long-range modulation of the integrated local density of states (LDOS), and quantify this modulation with respect to the moir\'e superstructure for multiple orientations of the monolayer with respect to the substrate. Scanning tunneling spectroscopy reveals a prominent peak in the LDOS, which is shifted in energy at different points of the moir\'e superstructure. Comparing ab initio calculations with angle-resolved photoemission, we are able to attribute this peak to bands that exhibit out-of-plane d-orbital character. We further identify an instability wave vector in the calculated electronic susceptibility of the free-standing layer, that coincides with a higher-order Fourier component of the moir\'e superstructure, suggesting the possibility of a complex interplay between the moir\'e superstructure, electronic structure and electronic instabilities in this material system.