Torsional instability in the single-chain limit of a transition metal 
trichalcogenide

Pham, Thang; Oh, Sehoon; Stetz, Patrick; Onishi, Seita; Kisielowski, Christian; Cohen, Marvin L.; Zettl, Alex

doi:10.1126/science.aat4749

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Torsional instability in the single-chain limit of a transition metal trichalcogenide

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Onishi, Seita
Physics of Unconventional Metals and Superconductors, Max Planck Institute for Chemical Physics of Solids, Max Planck Society;

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Citation

Pham, T., Oh, S., Stetz, P., Onishi, S., Kisielowski, C., Cohen, M. L., et al. (2018). Torsional instability in the single-chain limit of a transition metal trichalcogenide. Science, 361(6399), 263-266. doi:10.1126/science.aat4749.

Cite as: https://hdl.handle.net/21.11116/0000-0001-E1F2-F

Abstract

The scientific bounty resulting from the successful isolation of few to single layers of two-dimensional materials suggests that related new physics resides in the few-to single-chain limit of one-dimensional materials. We report the synthesis of the quasi-one-dimensional transition metal trichalcogenide NbSe3 (niobium triselenide) in the few-chain limit, including the realization of isolated single chains. The chains are encapsulated in protective boron nitride or carbon nanotube sheaths to prevent oxidation and to facilitate characterization. Transmission electron microscopy reveals static and dynamic structural torsional waves not found in bulk NbSe3 crystals. Electronic structure calculations indicate that charge transfer drives the torsional wave instability. Very little covalent bonding is found between the chains and the nanotube sheath, leading to relatively unhindered longitudinal and torsional dynamics for the encapsulated chains.