First-principles studies of defect-induced electron-phonon interactions in 2D semiconductors

Point defects have played an important role in semiconductor physics to tune physical and chemical properties of the host material. A variety of point defects have been uncovered in monolayer transition-metal dichalcogenides (TMDs), showing unique fingerprints in structural, electronic, and vibronic properties. In this talk, I will summarize calculations of electron-phonon interactions in monolayer TMDs with point defects using density functional theory and density-functional perturbation theory. We find that local atomic-scale structure in the vicinity of point defects is distorted, leading to spatially-localized electronic states, which in turn possess strong electron-phonon coupling. We discuss our calculations in the context of ongoing scanning tunneling spectroscopy measurements.