Frontiers of Plasmonics 被引量：1

Frontiers of Plasmonics

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摘要 Plasmonics, an important branch of nanooptics, has seen its prosperous development and exciting applications during the past years [1 3]. Surface plasmons （SPs）, the light-driven collective oscillation of free electrons in metals, include the localized type （localized surface plasmons, LSPs） and propagating type （surface plasmon polaritons, SPPs）. The most charming characteristics of SPs are the strong confinement of electromagnetic （EM） field （and thus EM enhancement） and long range propagation of EM energy （in case of SPPs）. Based on these characters, intriguing applications in many fields have been found, for example, single molecule spectroscopy using surface- enhanced Raman scattering （SERS） [4-7], ultrasensitive detection of chemical and biological species using localized surface plasmon resonance （LSPR） sensor [8, 9], spaser that stems from the amplification of resonant SPs in the cavity of metal nanostructures [10-12], superlens that utilizes the sub-wavelength concentration of SPs [13, 14], and plasmonic circuits that are based on the propagation modulation of SPPs [15-17]. Plasmonics, an important branch of nanooptics, has seen its prosperous development and exciting applications during the past years [1 3]. Surface plasmons （SPs）, the light-driven collective oscillation of free electrons in metals, include the localized type （localized surface plasmons, LSPs） and propagating type （surface plasmon polaritons, SPPs）. The most charming characteristics of SPs are the strong confinement of electromagnetic （EM） field （and thus EM enhancement） and long range propagation of EM energy （in case of SPPs）. Based on these characters, intriguing applications in many fields have been found, for example, single molecule spectroscopy using surface- enhanced Raman scattering （SERS） [4-7], ultrasensitive detection of chemical and biological species using localized surface plasmon resonance （LSPR） sensor [8, 9], spaser that stems from the amplification of resonant SPs in the cavity of metal nanostructures [10-12], superlens that utilizes the sub-wavelength concentration of SPs [13, 14], and plasmonic circuits that are based on the propagation modulation of SPPs [15-17].

作者 Lian-Ming Tong Hong-Xing Xu

机构地区 Laboratory of Nanoscale Physics and Devices

出处《Frontiers of physics》 SCIE CSCD 2014年第1期1-2,共2页 物理学前沿（英文版）

分类号 O657.37 [理学—分析化学] TB383 [一般工业技术—材料科学与工程]

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1Yuko S. Yamamoto,Mitsuru Ishikawa,Yukihiro Ozaki,Tamitake Itoh.Fundamental studies on enhancement and blinking mechanism of surface-enhanced Raman scattering （SERS） and basic applications of SERS biological sensing[J].Frontiers of physics,2014,9(1):31-46. 被引量：8
2Liang-Ping Xia,Zheng Yang,Shao-Yun Yin,Wen-Rui Guo,Jing-Lei Du,Chun-Lei Du.Hole arrayed metal-insulator-metal structure for surface enhanced Raman scattering by self-assembling polystyrene spheres[J].Frontiers of physics,2014,9(1):64-68. 被引量：4
3Katherine A. Willets.Plasmon point spread functions： How do we model plasmon-mediated emission processes？[J].Frontiers of physics,2014,9(1):3-16. 被引量：3
4Atsushi Ono,Masakazu Kikawada,Wataru Inami,Yoshimasa Kawata.Surface plasmon coupled fluorescence in deep-ultraviolet excitation by Kretschmann configuration[J].Frontiers of physics,2014,9(1):60-63. 被引量：2
5Yizhuo He,Junxue Fu,Yiping Zhao.Oblique angle deposition and its applications in plasmonics[J].Frontiers of physics,2014,9(1):47-59. 被引量：2
6Zee Hwan Kim.Single-molecule surface-enhanced Raman scattering： Current status and future perspective[J].Frontiers of physics,2014,9(1):25-30. 被引量：6

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