Colloquium: Dr. Peter Nordlander, Rice University
Location
Physics : 401
Date & Time
September 9, 2015, 3:30 pm – 4:30 pm
Description
TITLE: Plasmonics: From quantum effects to light harvesting applications
ABSTRACT: The “plasmon hybridization” concept,[1] shows that the plasmon resonances in complex metallic nanostructures interact and hybridize in an analogous manner as atomic wavefunctions in molecules. The insight gained from this concept provides a conceptual foundation for the development of new plasmonic structures that can serve as substrates for surface enhanced spectroscopies, chemical and biosensing, and subwavelength plasmonic waveguiding and other applications. The talk is comprised of basic overview material for a general audience interspersed with a few more specialized “hot topics” such quantum plasmonics,[2] aluminum plasmonics,[3] graphene and molecular plasmonics,[4] plasmon-induced vapor generation,[5] active plasmonic nanoantennas for enhanced light harvesting, hot carrier generation, and photocatalysis.[6]
[1] N.J. Halas et al., Adv. Mat. 24(2012)4842 [2] R. Esteban et al., Faraday Disc. 178(2015)151 [3] M.W. Knight et al., ACS Nano 8(2014)834; M.J. McClain et al., Nano Lett. 15(2015)2751 [4] Z.Y. Fang et al., Nano Lett. 14(2014)299; A. Lauchner et al.10.1021/acs.nanolett.5b02549 [5] O. Neumann et al., ACS Nano 7(2013)42; N.J. Hogan et al., Nano Lett. 14(2014)4640 [6] M.L Brongersma et al., Nature Nano 10(2015)25
ABSTRACT: The “plasmon hybridization” concept,[1] shows that the plasmon resonances in complex metallic nanostructures interact and hybridize in an analogous manner as atomic wavefunctions in molecules. The insight gained from this concept provides a conceptual foundation for the development of new plasmonic structures that can serve as substrates for surface enhanced spectroscopies, chemical and biosensing, and subwavelength plasmonic waveguiding and other applications. The talk is comprised of basic overview material for a general audience interspersed with a few more specialized “hot topics” such quantum plasmonics,[2] aluminum plasmonics,[3] graphene and molecular plasmonics,[4] plasmon-induced vapor generation,[5] active plasmonic nanoantennas for enhanced light harvesting, hot carrier generation, and photocatalysis.[6]
[1] N.J. Halas et al., Adv. Mat. 24(2012)4842 [2] R. Esteban et al., Faraday Disc. 178(2015)151 [3] M.W. Knight et al., ACS Nano 8(2014)834; M.J. McClain et al., Nano Lett. 15(2015)2751 [4] Z.Y. Fang et al., Nano Lett. 14(2014)299; A. Lauchner et al.10.1021/acs.nanolett.5b02549 [5] O. Neumann et al., ACS Nano 7(2013)42; N.J. Hogan et al., Nano Lett. 14(2014)4640 [6] M.L Brongersma et al., Nature Nano 10(2015)25