Decoupling Molybdenum Disulfide from its Substrate by Cesium Intercalation
Abstract
Intercalation of alkali atoms within the lamellar transition metal dichalcogenides is a possible route toward a new generation of batteries. It is also a way to induce structural phase transitions authorizing the realization of optical and electrical switches in this class of materials. The process of intercalation has been mostly studied in three-dimensional dichalcogenide films. Here, we address the case of a single-layer of molybdenum disulfide (MoS), deposited on a gold substrate, and intercalated with cesium (Cs) in ultra-clean conditions (ultrahigh vacuum). We show that intercalation decouples MoS from its substrate. We reveal electron transfer from Cs to MoS, relative changes in the energy of the valence band maxima, and electronic disorder induced by structural disorder in the intercalated Cs layer. Besides, we find an abnormal lattice expansion of MoS, which we relate to immediate vicinity of Cs. Intercalation is thermally activated, and so is the reverse process of de-intercalation. Our work opens the route to a microscopic understanding of a process of relevance in several possible future technologies, and shows a way to manipulate the properties of two-dimensional dichalcogenides by "under-cover" functionalization.
Keywords
Cite
@article{arxiv.2006.05765,
title = {Decoupling Molybdenum Disulfide from its Substrate by Cesium Intercalation},
author = {Roberto Sant and Simone Lisi and Van Dung Nguyen and Estelle Mazaleyrat and Ana Cristina Gómez Herrero and Olivier Geaymond and Valérie Guisset and Philippe David and Alain Marty and Matthieu Jamet and Claude Chapelier and Laurence Magaud and Yannick J. Dappe and Marco Bianchi and Philip Hofmann and Gilles Renaud and Johann Coraux},
journal= {arXiv preprint arXiv:2006.05765},
year = {2020}
}
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6 figures