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Controlled Growth of 1D MoSe2 Nanoribbons with Spatially Modulated Edge States

TitleControlled Growth of 1D MoSe2 Nanoribbons with Spatially Modulated Edge States
Publication TypeJournal Article
Year of Publication2017
AuthorsCheng, Fang, Xu Hai, Xu Wentao, Zhou Pinjia, Martin Jens, and Loh Kian Ping
JournalNano Lett.
Volume17
Pagination1116–1120
Date Published02/2017
ISSN1530-6984
Keywordsau(001), contacts, edge state, Moire pattern, molecular beam epitaxy, molybdenum-disulfide, monolayers, nanoribbon, nanosheets, nanowires, Scanning tunneling microscopy, single-layer mos2, surface, transistors, Transition metal dichalcogenides, transition-metal dichalcogenides
Abstract

Two-dimensional (2D) transition metal dichalcogenides (TMDCs) possess interesting one-dimensional (1D) properties at its edges and inversion domain boundaries, where properties markedly different from the 2D basal plane, such as 1D metallicity and charge density waves, can be observed. Although 2D TMDCs crystals are widely grown by chemical vapor deposition (CVD), the fabrication of 1D TMDCs ribbons is challenging due to the difficulty to confine growth in only one dimension. Here we report the controlled growth of MoSe2 nanoribbons with an aspect ratio {\textgreater}100 by using prepatterned Se reconstructions on Au(100). Using scanning tunneling microscope and spectroscopy (STM/STS), the atomic and electronic structure of MoSe2 nanoribbons are studied. The ultranarrow ribbons show metallic behavior, while wider ribbons show a crossover from metallic to semiconducting behavior going from the edge to the center of the ribbon. The observed conductance modulations of the ultranarrow ribbons are attributed to 1D Moire pattern. Remarkably, it shows a different periodicity compared with the 2D Moire pattern in wider ribbons indicating that the ID system is softened due to the high ratio of edge to basal plane bonds. Further, we demonstrated that the nanoribbons are stable against ambient conditions, which suggests that ID TMDCs can be exploited for further applications.

DOI10.1021/acs.nanolett.6b04715

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