网站地图 加入收藏 中文 English
澳门太阳集团网站入口 中心概况 研究队伍 科学研究 交流合作 人才培养 人才招聘
专题学术讲座

2016年6月8日(周三)下午4点, 量子物质科学协同创新中心 & 物理系seminar:

报告题目: Ac engineering of spin transfer torques in magnetic tunneling junctions 报 告 人: 陈晓彬                 McGill University 报告时间: 2016-6-8    16:00 报告地点: 理科楼B406 摘要: Phenomena of spin transfer torques (STTs) have been attracting persistent interests due to promising prospects of STTs in designing nano devices. By using nonequilibrium Green's function method, we derive time-averaged formulism for spin transfer torques in a noncollinear magnetic tunneling system under ac modulation within wide-band-limit approximation. Using these formulas, we further investigate ac spin transfer torques in a carbon-nanotube-based magnetic tunneling system. It shows that under ac modulation, the low-bias linear (quadratic) dependence of the in-plane (out-of-plane) torque on bias still holds, and the regular angular dependence on noncollinear angle is maintained. By introducing photon-assisted tunneling, the bias-induced components of the in-plane and out-of-plane torques can be enhanced by about 10 and 80 times, respectively. Further analysis shows that optimized enhancement can be achieved by using ac driving frequency w=e0/k, k=1,2,..., where e0 marks a remote dc transmission peak, and using ac amplitude D such that D/w maximizes a kth-order Bessel function of the first kind. Out findings suggest that ac modulation is a promising way for electrical manipulation of spin transfer torques, paving the road towards emerging nanoelectronic and spintronic devices utilizing spin transfer torques. 个人简介: Dr. Chen works on theoretical Physics as a postdoctoral fellow in the department of Physics at McGill University, Canada. She received her Ph.D. of condensed matter Physics from Tsinghua University in 2014 and has been conducting her postdoctoral research with Prof. Hong Guo at McGill University since then. Her early research interests were nanoscale heat transport and thermoelectricity. More recently, she has worked on the spin Caloritronics, spin thermoelectrics, valley transport, and time-dependent physics in nanostructures.



版权所有 量子物质科学协同创新中心

本页已经浏览