Phase change dispersion of plasmonic nano-objects

Xie Zeng; Haifeng Hu; Yongkang Gao; Dengxin Ji; Nan Zhang; Haomin Song; Kai Liu; Suhua Jiang; Qiaoqiang Gan

doi:10.1038/srep12665

Phase change dispersion of plasmonic nano-objects

Xie Zeng, Haifeng Hu, Yongkang Gao, Dengxin Ji, Nan Zhang, Haomin Song, Kai Liu, Suhua Jiang^*, Qiaoqiang Gan

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

Phase is an inherent and important feature for coherent processes, which, unfortunately, has not been completely understood for surface plasmon polariton (SPP) and matter interactions. Here we propose a practical approach to extract the phase change dispersion during the interaction between free-space light, SPPs and nanogroove/slit based on far-field information only. Numerical simulation and experimental validation were both presented using nanoslit-groove plasmonic interferometers, agreeing well with theoretical near-field analysis. This approach is generally feasible to extract the intrinsic phase dispersion of other plasmonic nanostructures and can reveal more fundamental features of SPP-matter interactions.

Original language	English
Article number	12665
Journal	Scientific Reports
Volume	5
DOIs	https://doi.org/10.1038/srep12665
Publication status	Published - 29 Jul 2015
Externally published	Yes

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abstract = "Phase is an inherent and important feature for coherent processes, which, unfortunately, has not been completely understood for surface plasmon polariton (SPP) and matter interactions. Here we propose a practical approach to extract the phase change dispersion during the interaction between free-space light, SPPs and nanogroove/slit based on far-field information only. Numerical simulation and experimental validation were both presented using nanoslit-groove plasmonic interferometers, agreeing well with theoretical near-field analysis. This approach is generally feasible to extract the intrinsic phase dispersion of other plasmonic nanostructures and can reveal more fundamental features of SPP-matter interactions.",

author = "Xie Zeng and Haifeng Hu and Yongkang Gao and Dengxin Ji and Nan Zhang and Haomin Song and Kai Liu and Suhua Jiang and Qiaoqiang Gan",

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T1 - Phase change dispersion of plasmonic nano-objects

AU - Zeng, Xie

AU - Hu, Haifeng

AU - Gao, Yongkang

AU - Ji, Dengxin

AU - Zhang, Nan

AU - Song, Haomin

AU - Liu, Kai

AU - Jiang, Suhua

AU - Gan, Qiaoqiang

PY - 2015/7/29

Y1 - 2015/7/29

N2 - Phase is an inherent and important feature for coherent processes, which, unfortunately, has not been completely understood for surface plasmon polariton (SPP) and matter interactions. Here we propose a practical approach to extract the phase change dispersion during the interaction between free-space light, SPPs and nanogroove/slit based on far-field information only. Numerical simulation and experimental validation were both presented using nanoslit-groove plasmonic interferometers, agreeing well with theoretical near-field analysis. This approach is generally feasible to extract the intrinsic phase dispersion of other plasmonic nanostructures and can reveal more fundamental features of SPP-matter interactions.

AB - Phase is an inherent and important feature for coherent processes, which, unfortunately, has not been completely understood for surface plasmon polariton (SPP) and matter interactions. Here we propose a practical approach to extract the phase change dispersion during the interaction between free-space light, SPPs and nanogroove/slit based on far-field information only. Numerical simulation and experimental validation were both presented using nanoslit-groove plasmonic interferometers, agreeing well with theoretical near-field analysis. This approach is generally feasible to extract the intrinsic phase dispersion of other plasmonic nanostructures and can reveal more fundamental features of SPP-matter interactions.

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SN - 2045-2322

VL - 5

JO - Scientific Reports

JF - Scientific Reports

M1 - 12665

ER -

Phase change dispersion of plasmonic nano-objects

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