Quantitative study of the photothermal properties of metallic nanowire networks

Alan P. Bell; Jessamyn A. Fairfield; Eoin K. McCarthy; Shaun Mills; John J. Boland; Guillaume Baffou; David McCloskey

doi:10.1021/acsnano.5b01673

Quantitative study of the photothermal properties of metallic nanowire networks

Alan P. Bell, Jessamyn A. Fairfield, Eoin K. McCarthy, Shaun Mills, John J. Boland, Guillaume Baffou, David McCloskey

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

66 Citations (Scopus)

Abstract

In this article, we present a comprehensive investigation of the photothermal properties of plasmonic nanowire networks. We measure the local steady-state temperature increase, heat source density, and absorption in Ag, Au, and Ni metallic nanowire networks under optical illumination. This allows direct experimental confirmation of increased heat generation at the junction between two metallic nanowires and stacking-dependent absorption of polarized light. Due to thermal collective effects, the local temperature distribution in a network is shown to be completely delocalized on a micrometer scale, despite the nanoscale features in the heat source density. Comparison of the experimental temperature profile with numerical simulation allows an upper limit for the effective thermal conductivity of a Ag nanowire network to be established at 43 Wm^-1 K^-1 (0.1 κ_bulk).

Original language	English
Pages (from-to)	5551-5558
Number of pages	8
Journal	ACS Nano
Volume	9
Issue number	5
DOIs	https://doi.org/10.1021/acsnano.5b01673
Publication status	Published - 26 May 2015
Externally published	Yes

Keywords

nanowelding
nanowire networks
temperature microscopy
thermoplasmonics

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10.1021/acsnano.5b01673

Cite this

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title = "Quantitative study of the photothermal properties of metallic nanowire networks",

abstract = "In this article, we present a comprehensive investigation of the photothermal properties of plasmonic nanowire networks. We measure the local steady-state temperature increase, heat source density, and absorption in Ag, Au, and Ni metallic nanowire networks under optical illumination. This allows direct experimental confirmation of increased heat generation at the junction between two metallic nanowires and stacking-dependent absorption of polarized light. Due to thermal collective effects, the local temperature distribution in a network is shown to be completely delocalized on a micrometer scale, despite the nanoscale features in the heat source density. Comparison of the experimental temperature profile with numerical simulation allows an upper limit for the effective thermal conductivity of a Ag nanowire network to be established at 43 Wm-1 K-1 (0.1 κbulk).",

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AU - Bell, Alan P.

AU - Fairfield, Jessamyn A.

AU - McCarthy, Eoin K.

AU - Mills, Shaun

AU - Boland, John J.

AU - Baffou, Guillaume

AU - McCloskey, David

PY - 2015/5/26

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N2 - In this article, we present a comprehensive investigation of the photothermal properties of plasmonic nanowire networks. We measure the local steady-state temperature increase, heat source density, and absorption in Ag, Au, and Ni metallic nanowire networks under optical illumination. This allows direct experimental confirmation of increased heat generation at the junction between two metallic nanowires and stacking-dependent absorption of polarized light. Due to thermal collective effects, the local temperature distribution in a network is shown to be completely delocalized on a micrometer scale, despite the nanoscale features in the heat source density. Comparison of the experimental temperature profile with numerical simulation allows an upper limit for the effective thermal conductivity of a Ag nanowire network to be established at 43 Wm-1 K-1 (0.1 κbulk).

AB - In this article, we present a comprehensive investigation of the photothermal properties of plasmonic nanowire networks. We measure the local steady-state temperature increase, heat source density, and absorption in Ag, Au, and Ni metallic nanowire networks under optical illumination. This allows direct experimental confirmation of increased heat generation at the junction between two metallic nanowires and stacking-dependent absorption of polarized light. Due to thermal collective effects, the local temperature distribution in a network is shown to be completely delocalized on a micrometer scale, despite the nanoscale features in the heat source density. Comparison of the experimental temperature profile with numerical simulation allows an upper limit for the effective thermal conductivity of a Ag nanowire network to be established at 43 Wm-1 K-1 (0.1 κbulk).

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KW - temperature microscopy

KW - thermoplasmonics

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Quantitative study of the photothermal properties of metallic nanowire networks

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Keywords

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