Light-induced coalescence of plasmonic dimers and clusters

Andrew R. Salmon; Marie-Elena  Kleemann; Junyang  Huang; William M  Deacon; Cloudy Carnegie; Marlous  Kamp; Bart De Nijs; Angela Demetriadou; Jeremy J. Baumberg

doi:10.1021/acsnano.0c01213

Light-induced coalescence of plasmonic dimers and clusters

Andrew R. Salmon, Marie-Elena Kleemann, Junyang Huang, William M Deacon, Cloudy Carnegie, Marlous Kamp, Bart De Nijs, Angela Demetriadou, Jeremy J. Baumberg

Physics and Astronomy

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

5 Citations (Scopus)

242 Downloads (Pure)

Abstract

The properties of nanoplasmonic structures depend strongly on their geometry, creating the need for high-precision control and characterization. Here, by exploiting the low activation energy of gold atoms on nanoparticle surfaces, we show how laser irradiation reshapes nanoparticle dimers. Time-course dark-field microspectroscopy allows this process to be studied in detail for individual nanostructures. Three regimes are identified: facet growth, formation of a conductive bridge between particles, and bridge growth. Electromagnetic simulations confirm the growth dynamics and allow measurement of bridge diameter, found to be highly reproducible and also self-limiting. Correlations in spectral resonances for the initial and final states give insight into the energy barriers for bridge growth. Dark-field microscopy shows that coalescence of multiple gaps in nanoparticle clusters can be digitally triggered, with each gap closing after discrete increases in irradiation power. Such control is important for light-induced nanowire formation or trimming of electronic and optoelectronic devices.

Original language	English
Pages (from-to)	4982-4987
Number of pages	6
Journal	ACS Nano
Volume	14
Issue number	4
Early online date	25 Mar 2020
DOIs	https://doi.org/10.1021/acsnano.0c01213
Publication status	Published - 1 Apr 2020

Keywords

gold nanoparticles
nanoparticle coalescence
nanoparticle dimers
optical spectroscopy
plasmonics
sintering

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10.1021/acsnano.0c01213Licence: None: All rights reserved

Salmon_et_al_Light-induced_coalescence_ACS_Nano_2020
This document is the Accepted Manuscript version of a Published Work that appeared in final form in ACS Nano, copyright © American Chemical Society after peer review and technical editing by the publisher. To access the final edited and published work see https://doi.org/10.1021/acsnano.0c01213
Accepted author manuscript, 1.03 MBLicence: None: All rights reserved

https://pubs.acs.org/doi/10.1021/acsnano.0c01213Licence: None: All rights reserved

Cite this

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title = "Light-induced coalescence of plasmonic dimers and clusters",

abstract = "The properties of nanoplasmonic structures depend strongly on their geometry, creating the need for high-precision control and characterization. Here, by exploiting the low activation energy of gold atoms on nanoparticle surfaces, we show how laser irradiation reshapes nanoparticle dimers. Time-course dark-field microspectroscopy allows this process to be studied in detail for individual nanostructures. Three regimes are identified: facet growth, formation of a conductive bridge between particles, and bridge growth. Electromagnetic simulations confirm the growth dynamics and allow measurement of bridge diameter, found to be highly reproducible and also self-limiting. Correlations in spectral resonances for the initial and final states give insight into the energy barriers for bridge growth. Dark-field microscopy shows that coalescence of multiple gaps in nanoparticle clusters can be digitally triggered, with each gap closing after discrete increases in irradiation power. Such control is important for light-induced nanowire formation or trimming of electronic and optoelectronic devices.",

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AU - Salmon, Andrew R.

AU - Kleemann, Marie-Elena

AU - Huang, Junyang

AU - Deacon, William M

AU - Carnegie, Cloudy

AU - Kamp, Marlous

AU - De Nijs, Bart

AU - Demetriadou, Angela

AU - Baumberg, Jeremy J.

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N2 - The properties of nanoplasmonic structures depend strongly on their geometry, creating the need for high-precision control and characterization. Here, by exploiting the low activation energy of gold atoms on nanoparticle surfaces, we show how laser irradiation reshapes nanoparticle dimers. Time-course dark-field microspectroscopy allows this process to be studied in detail for individual nanostructures. Three regimes are identified: facet growth, formation of a conductive bridge between particles, and bridge growth. Electromagnetic simulations confirm the growth dynamics and allow measurement of bridge diameter, found to be highly reproducible and also self-limiting. Correlations in spectral resonances for the initial and final states give insight into the energy barriers for bridge growth. Dark-field microscopy shows that coalescence of multiple gaps in nanoparticle clusters can be digitally triggered, with each gap closing after discrete increases in irradiation power. Such control is important for light-induced nanowire formation or trimming of electronic and optoelectronic devices.

AB - The properties of nanoplasmonic structures depend strongly on their geometry, creating the need for high-precision control and characterization. Here, by exploiting the low activation energy of gold atoms on nanoparticle surfaces, we show how laser irradiation reshapes nanoparticle dimers. Time-course dark-field microspectroscopy allows this process to be studied in detail for individual nanostructures. Three regimes are identified: facet growth, formation of a conductive bridge between particles, and bridge growth. Electromagnetic simulations confirm the growth dynamics and allow measurement of bridge diameter, found to be highly reproducible and also self-limiting. Correlations in spectral resonances for the initial and final states give insight into the energy barriers for bridge growth. Dark-field microscopy shows that coalescence of multiple gaps in nanoparticle clusters can be digitally triggered, with each gap closing after discrete increases in irradiation power. Such control is important for light-induced nanowire formation or trimming of electronic and optoelectronic devices.

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Light-induced coalescence of plasmonic dimers and clusters

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Keywords

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