网站地图 加入收藏 中文 English
首页 中心概况 研究队伍 科学研究 交流合作 人才培养 人才招聘
当前位置: 首页 - 交流合作 - 专题学术讲座 - 正文
专题学术讲座

2015年10月29日(周四)下午13:30,量子物质科学协同创新中心&物理系seminar:

报告题目: Development of Nuclear Magnetic Resonance Techniques For the Study of Topological Band Structures 报 告 人: Louis Bouchard,UCLA 报告时间: 2015-10-29   13:30 报告地点: 理科楼B406 摘要: In recent years, the emergence of gapless topologically protected edge states in the solid state without the need to apply an external field has led to searches for new phases of condensed matter in new and existing materials.   For example, some thermoelectrics and Kondo insulators have been shown to be topological insulators (TIs).  The edge states give rise to exotic phenomena include the quantum anomalous Hall effect, fractional quantum anomalous Hall effect, topological superconductor, fractional time-reversal invariance, topological crystalline insulator and the topological magneto-electric effect.   Because the interesting properties of TIs are found at edges and interfaces, they are challenging to study experimentally.  In this talk, I will present new experimental approaches to study the electronic and magnetic properties of such topological materials based on nuclear spin interactions (namely, using nuclear magnetic resonance, NMR).  Among the techniques, we shall discuss a type of radioactive ion beam spectroscopy to resolve properties as function of depth, and with nanoscale resolution.  Such studies not only reveal substantial modulations of the material properties at these length scales, but also reveal new parameters such as s-d exchange integrals which cannot be obtained by other means.  Because they do not rely on transport, NMR techniques may offer new and less ambiguous ways to separate bulk from surface contributions.  Unlike ARPES, the method is not limited to n-type materials and one can easily probe p-type materials.  NMR is also useful in the case of materials with high defect content even up to room temperature.    I will discuss the distinct responses of nuclear spins based on dipolar and quadrupolar moments.  The new methods could have implications in the design of devices, in the search for novel physics and in the optimization of material properties.             个人简介: Dr. Bouchard obtained a bachelor's degree in physics and business management from McGill University in Montréal, Canada, a Master's degree in medical biophysics from the University of Toronto and a Ph.D. in Chemistry from Princeton University. His doctoral dissertation explores the use of multiple quantum coherence and long-range dipolar interactions in condensed matter to characterize heterogeneous material microstructure. During his stay in the laboratory of Alex Pines at the University of California, Berkeley he developed novel approaches and methodologies to portable, low-field NMR and MRI, microfluidics and hyperpolarization methods to the study of chemical reactions. He joined the UCLA faculty during the summer of 2008 to pursue research in physical chemistry.



版权所有 量子物质科学协同创新中心

本页已经浏览