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26日(周四)上午10点,量子物质科学协同创新中心 & 物理系seminar:

报告题目: Manipulating Strong Light-Matter Interactions In Graphene and 2D Semiconductors 报 告 人: Sufei Shi             UC Berkeley/Lawrence Berkeley National Laboratory 报告时间: 2015-3-26  10:00 报告地点: 理科楼三楼报告厅(C302) 摘要: Graphene, a single atomic layer of carbon atoms arranged in a honeycomb lattice, has linear bandstructure which leads to its unique electronic and optical properties. Light matter interaction is particularly strong in graphene. We exploit this interaction in the visible to infrared regime for graphene based optoelectronic devices. We use both scanning photocurrent microscopy and optical pump terahertz (THz) probe spectroscopy to reveal hot carrier behavior in graphene. This hot carrier behavior is crucial to understand the effect of optical excitation on graphene and can potentially lead to efficient solar energy conversion and ultrafast optoelectronic devices. We also exploit the strong light matter interaction in THz regime to make graphene based THz modulator.
Transitional metal dichalcogenide (TMD), labelled as MX2 (M - Mo, W; X - S, Se), is a new class of 2D semiconductors which undergo an indirect bandgap to direct bandgap transition when it is thinned down to one monolayer layer. MX2 exhibits intriguing optical phenomena such as valley selective circular dichroism, exotic excitonic physics, etc. In particular, MX2 show unprecedentedly strong optical absorption, with one single layer absorbing more than 10% of the light. We combine optical spectroscopy and scanning tunneling microscopy to determine the extraordinarily large exciton binding energy of MoS2, which is more than one order of magnitude larger that of traditional semiconductors. This large binding energy results from the strong Coulomb interaction in 2D, and MX2 provides a unique platform to study exotic exciton physics. However, the giant exciton binding energy also presents a challenge for efficient carrier separation in solar cell applications. We demonstrate that, by using MoS2/WS2 heterostructure, we can achieve type-II band alignment and realize extremely fast carrier separation.
报告人简介: Sufei Shi is a Postdoc fellow at the Physics Department of UC Berkeley, working on optical spectroscopy study of two-dimensional (2D) materials. He obtained his Ph.D. degree under the guidance of Prof. Dan Ralph at Cornell Univ. in Jan, 2012. His Ph.D. research was focused on spatially-resolved and time-resolved scanning photocurrent microscopy on graphene based devices, fabrication of metal nano-contact and single electron transistor devices, as well as electrical transport measurement of these devices at ~ 10 mK and high magnetic field.  Dr. Shi is currently working on optical spectroscopy of 2D materials, with a particular focus on terahertz (THz) spectroscopy. Dr. Shi will start as an Assistant Professor at the Chemical and Biological Engineering Department of Renssellaer Polytechnic Institute (RPI) from July, 2015.



版权所有 量子物质科学协同创新中心

本页已经浏览