【校级报告】Mesoscopic electrodynamics: Quantum and nonlocal plasmonic response at metal surfaces

发布日期：2022-09-09 作者：秦梦瑶浏览次数：62

报告人：N. Asger Mortensen, Professor & VILLUM Investigator University of Southern Denmark

主持人：朱晓龙研究员

时间：2022年9月16日（周五）下午15:00

地点：ZOOM会议ID：84952767618，密码：123456 / 光学大楼B325会议室

参会链接:https://us02web.zoom.us/j/84952767618

报告人简介：

Mortensen is a full professor & VILLUM Investigator in the Center for Nano Optics and a Chair of Technical Science in the Danish Institute for Advanced Study, both at the University of Southern Denmark. Previously, he held a full professorship (faculty since 2004) at the Technical University of Denmark (DTU). In addition to his MSc (1998) and PhD (2001) degrees from DTU, he holds higher doctoral degrees from University of Copenhagen (Dr. Scient., 2021) and DTU (Dr. Tech., 2006). He is a fellow of APS, OSA, SPIE, IOP, and European Academy of Sciences. Currently, he serves the AAAS as an associate editor for Science Advances.

报告内容简介：

Plasmonic phenomena in metals are commonly explored within the framework of classical electrodynamics and semiclassical models for the interactions of light with free-electron matter. The more detailed understanding of mesoscopic electrodynamics at metal surfaces is, however, becoming increasingly important for both fundamental developments in quantum plasmonics [1] and potential applications in emerging light-based quantum technologies [2]. While this intuitively calls for a full quantum description of plasmon-enhanced light-matter interactions, recent discoveries suggest how classical electrodynamics may still suffice if appropriately dressed by quantum-corrected mesoscopic boundary conditions [3-5]. Recently, consequences have been explored for a plethora of plasmon-emitter interactions ranging from dipolar and multipolar spontaneous emission enhancement, to plasmon-assisted energy transfer and enhancement of two-photon transitions [6].

[1] N.A. Mortensen, “Mesoscopic electrodynamics at metal surfaces – From quantum-corrected hydrodynamics to microscopic surface-response formalism”, Nanophotonics 10, 2563 (2021)

[2] A.I. Fernández-Domínguez, S.I. Bozhevolnyi & N.A. Mortensen, “Plasmon-enhanced generation of non-classical light”, ACS Photonics 5, 3447 (2018).

[3] W. Yan et al., “Projected Dipole Model for Quantum Plasmonics”,Phys. Rev. Lett. 115, 137403 (2015).
[4] T. Christensen et al., “Quantum corrections in nanoplasmonics: shape, scale, and material”,Phys. Rev. Lett. 118, 157402 (2017).
[5] Y. Yang et al., “A General Theoretical and Experimental Framework for Nanoscale Electromagnetism”, Nature 576, 248 (2019).
[6] P.A.D. Gonçalves et al., ”Plasmon-Emitter Interactions at the Nanoscale”,Nat. Commun. 11, 366 (2020).