| Literature DB >> 25574856 |
Shan Zhang1, Ning Tang, Weifeng Jin, Junxi Duan, Xin He, Xin Rong, Chenguang He, Lisheng Zhang, Xudong Qin, Lun Dai, Yonghai Chen, Weikun Ge, Bo Shen.
Abstract
Spintronic devices rely on the spin degree of freedom (DOF), and spin orbit coupling (SOC) is the key to manipulate spin DOF. Quasi-one-dimensional structures, possessing marked anisotropy gives more choice for the manipulation of the spin DOF since the concrete SOC form varies along with crystallographic directions. The anisotropy of the Dresselhaus SOC in cadmium selenide (CdSe) nanobelt and nanowire was studied by circular photogalvanic effect. It was demonstrated that the Dresselhaus SOC parameter is zero along the [0001] crystallographic direction, which suppresses the spin relaxation and increases the spin diffusion length, and thus is beneficial to the spin manipulation. To achieve a device structure with Rashba SOC presence and Dresselhaus SOC absence for manipulating the spin DOF, an ionic liquid gate was produced on a nanowire grown along the [0001] crystallographic direction, and the Rashba SOC was induced by gating, as expected.Entities:
Keywords: CdSe nanobelt/nanowire; Dresselhaus SOC; Rashba spin orbit coupling (SOC); circular photogalvanic effect; ionic liquid
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Year: 2015 PMID: 25574856 DOI: 10.1021/nl504225c
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189