Optical properties of＇ Au-core Pt-shell nanorods studied using FDTD simulations

Optical properties of＇ Au-core Pt-shell nanorods studied using FDTD simulations

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摘要 Au-core/Pt-shell nanorods （Au@Pt NRs） have been prepared by a Au nanorod-mediated growth method, and they exhibit high electromagnetic field enhancements under coupling conditions. Boosted by a long-range effect of the high electromagnetic field generated by the Au core, the electromagnetic field enhancement can be controlled by changing the morphology of the nanostruc- tures. In this study, we report the results on the simulations of the electromagnetic field enhancement using a finite difference time domain （FDTD） method, taking the real shapes of the Au@Pt NRs into account. Due to the ＂hot spot＂ effect, the electromagnetic field can be localized between the Pt nanodots. The electromagnetic field enhancement is found to be rather independent of the Pt con- tent, whereas the local roughness and small sharp features might significantly modify the near-field. As the electromagnetic field enhancement can be tuned by the distribution of Pt nanodots over the Au-core, Au@Pt NRs can find potential applications in related areas. Au-core/Pt-shell nanorods （Au@Pt NRs） have been prepared by a Au nanorod-mediated growth method, and they exhibit high electromagnetic field enhancements under coupling conditions. Boosted by a long-range effect of the high electromagnetic field generated by the Au core, the electromagnetic field enhancement can be controlled by changing the morphology of the nanostruc- tures. In this study, we report the results on the simulations of the electromagnetic field enhancement using a finite difference time domain （FDTD） method, taking the real shapes of the Au@Pt NRs into account. Due to the ＂hot spot＂ effect, the electromagnetic field can be localized between the Pt nanodots. The electromagnetic field enhancement is found to be rather independent of the Pt con- tent, whereas the local roughness and small sharp features might significantly modify the near-field. As the electromagnetic field enhancement can be tuned by the distribution of Pt nanodots over the Au-core, Au@Pt NRs can find potential applications in related areas.

作者 Jian-Bo Liu Lin Long Yu-Shi Zhang Yue-Ping_Wang Feng-Shou Liu Wei-Yao Xu Ming-Ji Zong Lei Ma Wen-Qi Liu Hui Zhang JiaoYan Jia-Qi Chen Ying-LuJi Xiao—ChunWu

机构地区 College of Opto-electronic Engineering Zaozhuang Municipal Center for Disease Control and Prevention CAS Key Laboratory of Standardization and Measurement for Nanotechnology

出处《Frontiers of physics》 SCIE CSCD 2016年第3期123-131,共9页 物理学前沿（英文版）

关键词 GOLD PLATINUM CORE-SHELL nanorod FDTD gold, platinum, core-shell, nanorod, FDTD

分类号 O4 [理学—物理]

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Optical properties of＇ Au-core Pt-shell nanorods studied using FDTD simulations

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