Unveiling the multi-level structure of midgap states in Sb-doped MoX2 (X = S, Se, Te) monolayers

Abstract

In this study, we use DFT calculations to investigate the electronic and structural properties of MoX2 (X = S, Se, Te) monolayers doped with substitutional Sb atoms, with a central focus on the Sb(Mo) substitution. In MoS2, we observe that this substitution is energetically favored under S rich conditions, where the S2 gaseous phase is likely to be present. This result is compatible with a recent experimental observation in Sb-doped MoS2 nanosheets grown by CVD. A similar behavior is found in MoSe2, but in MoTe2 the Sb(Mo) substitution is less likely to occur due to the possible absence of gaseous Te phases in experimental setups. In all cases, several impurity-induced states are found inside the band gap, with energies that span the entire gap. The Fermi energy is pinned a few tenths of eV above the top of the valence band, suggesting a predominant p-type behavior. The orbital nature of these states is investigated with projected and local density of states calculations, which reveal similarities to defect states induced by single Mo vacancies as well as their rehybridization with the 5s orbital from Sb. Additionally, we find that the band gap of the doped systems is increased in comparison with the pristine materials, in contrast with a previous calculation in Sb-doped MoS2 that predicts a gap reduction with a different assignment of valence band and impurity levels. We discuss the similarities, discrepancies, and the limitations of both calculations. We also speculate possible reasons for the experimentally observed redshifts of the A and B excitons in the presence of the Sb dopants in MoS2. We hope that these results spark future investigations on other aspects of the problem, particularly those concerning the effects of disorder and electron-hole interaction, and continue to reveal the potential of doped TMDCs for applications in optoelectronic devices.

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