Conformational change-modulated spin transport at the single-molecule level in carbon systems --Invited for the Third Carbon Special Topic

• Published in: arXiv.org
• Main Authors: Yan-Dong, Guo, Zhao, Xue, Hong-Ru, Zhao, Yang, Li, Li-Yan, Lin, Jiang, Yue, Ma, Dan, Yu-Ting, Chen, Xiao-Hong, Yan
• Format: Paper Journal Article
• Language: English
• Published: Ithaca Cornell University Library, arXiv.org 16.11.2022
• Subjects: Carbon; Chemical synthesis; Electrode materials; Electrode polarization; Electrodes; Electron spin; Electron transport; Ferromagnetism; First principles; Functional groups; Graphene; Molecular chains; Physics - Atomic and Molecular Clusters; Polarization (spin alignment); Spintronics
• ISSN: 2331-8422
• DOI: 10.48550/arxiv.2211.08835

Controlling the spin transport at the single-molecule level, especially without the use of ferromagnetic contacts, becomes a focus of research in spintronics. Inspired by the progress on atomic-level molecular synthesis, through first-principles calculations, we investigate the spin-dependent electronic transport of graphene nanoflakes with side-bonded functional groups, contacted by atomic carbon chain electrodes. It is found that, by rotating the functional group, the spin polarization of the transmission at the Fermi level could be switched between completely polarized and unpolarized states. Moreover, the transition between spin-up and spin-down polarized states can also be achieved, operating as a dual-spin filter. Further analysis shows that, it is the spin-dependent shift of density of states, caused by the rotation, that triggers the shift of transmission peaks, and then results in the variation of spin polarization. Such a feature is found to be robust to the of the nanoflake and the electrode material, showing great application potential. Those findings may throw light on the development of spintronic devices.