Visualization of Plasmonic Couplings Using Ultrafast Electron Microscopy

Hybrids of graphene and metal plasmonic nanostructures are promising building blocks for applications in optoelectronics, surface-enhanced scattering, biosensing, and quantum information. An understanding of the coupling mechanism in these hybrid systems is of vital importance to its applications. P...

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Veröffentlicht in:	Nano letters 2021-07, Vol.21 (13), p.5842-5849
Hauptverfasser:	Liu, Haihua, Gage, Thomas E, Singh, Prem, Jaiswal, Amit, Schaller, Richard D, Tang, Jau, Park, Sang Tae, Gray, Stephen K, Arslan, Ilke
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Sprache:	eng
Schlagworte:	discrete dipole approximation gold nanocapsule graphene hybriding NANOSCIENCE AND NANOTECHNOLOGY photon-induced near-field electron microscopy plasmonic coupling ultrafast electron microscopy
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container_title	Nano letters
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creator	Liu, Haihua Gage, Thomas E Singh, Prem Jaiswal, Amit Schaller, Richard D Tang, Jau Park, Sang Tae Gray, Stephen K Arslan, Ilke
description	Hybrids of graphene and metal plasmonic nanostructures are promising building blocks for applications in optoelectronics, surface-enhanced scattering, biosensing, and quantum information. An understanding of the coupling mechanism in these hybrid systems is of vital importance to its applications. Previous efforts in this field mainly focused on spectroscopic studies of strong coupling within the hybrids with no spatial resolution. Here we report direct imaging of the local plasmonic coupling between single Au nanocapsules and graphene step edges at the nanometer scale by photon-induced near-field electron microscopy in an ultrafast electron microscope for the first time. The proximity of a step in the graphene to the nanocapsule causes asymmetric surface charge density at the ends of the nanocapsules. Computational electromagnetic simulations confirm the experimental observations. The results reported here indicate that this hybrid system could be used to manipulate the localized electromagnetic field on the nanoscale, enabling promising future plasmonic devices.
doi_str_mv	10.1021/acs.nanolett.1c01824
format	Article
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subjects	discrete dipole approximation gold nanocapsule graphene hybriding NANOSCIENCE AND NANOTECHNOLOGY photon-induced near-field electron microscopy plasmonic coupling ultrafast electron microscopy
title	Visualization of Plasmonic Couplings Using Ultrafast Electron Microscopy
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