Enhancing plasmonic hot-carrier generation by strong coupling of multiple resonant modes

Yat Lam Wong; Huaping Jia; Aoqun Jian; Dangyuan Lei; Abdel I. El Abed; Xuming Zhang

doi:10.1039/d0nr07643k

Enhancing plasmonic hot-carrier generation by strong coupling of multiple resonant modes

Yat Lam Wong, Huaping Jia, Aoqun Jian, Dangyuan Lei^*, Abdel I. El Abed, Xuming Zhang^*

^*Corresponding author for this work

Department of Materials Science and Engineering

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

17 Citations (Scopus)

Abstract

Plasmon-induced hot carriers have recently attracted considerable interest, but the energy efficiency in visible light is often low due to the short lifetime of hot carriers and the limited optical absorption of plasmonic architectures. To increase the generation of hot carriers, we propose to exert multiple plasmonic resonant modes and their strong coupling using a metal-dielectric-metal (MDM) nanocavity that comprises an Au nanohole array (AuNHA), a TiO2 thin film and an Au reflector. Unlike common MDM structures, in addition to the Fabry-Pérot mode in the dielectric layer, AuNHA as the top layer is special because it excites the localized surface plasmon resonance (LSPR) mode in the Au nanoholes and launches the gap surface plasmon polariton (GSPP) mode in the Au reflector surface. The spatial field overlapping of the three resonance modes enables strong mode coupling by optimizing the TiO2 thickness, which leads to notably enhanced average IPCE (∼1.5%) and broadband photocurrent (170 μA·cm^-2). This MDM structure would be useful for photochemistry and photovoltaics using sunlight. This journal is

Original language	English
Pages (from-to)	2792-2800
Journal	Nanoscale
Volume	13
Issue number	5
Online published	28 Dec 2020
DOIs	https://doi.org/10.1039/d0nr07643k
Publication status	Published - 7 Feb 2021

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AU - Wong, Yat Lam

AU - Jia, Huaping

AU - Jian, Aoqun

AU - Lei, Dangyuan

AU - El Abed, Abdel I.

AU - Zhang, Xuming

PY - 2021/2/7

Y1 - 2021/2/7

N2 - Plasmon-induced hot carriers have recently attracted considerable interest, but the energy efficiency in visible light is often low due to the short lifetime of hot carriers and the limited optical absorption of plasmonic architectures. To increase the generation of hot carriers, we propose to exert multiple plasmonic resonant modes and their strong coupling using a metal-dielectric-metal (MDM) nanocavity that comprises an Au nanohole array (AuNHA), a TiO2 thin film and an Au reflector. Unlike common MDM structures, in addition to the Fabry-Pérot mode in the dielectric layer, AuNHA as the top layer is special because it excites the localized surface plasmon resonance (LSPR) mode in the Au nanoholes and launches the gap surface plasmon polariton (GSPP) mode in the Au reflector surface. The spatial field overlapping of the three resonance modes enables strong mode coupling by optimizing the TiO2 thickness, which leads to notably enhanced average IPCE (∼1.5%) and broadband photocurrent (170 μA·cm-2). This MDM structure would be useful for photochemistry and photovoltaics using sunlight. This journal is

AB - Plasmon-induced hot carriers have recently attracted considerable interest, but the energy efficiency in visible light is often low due to the short lifetime of hot carriers and the limited optical absorption of plasmonic architectures. To increase the generation of hot carriers, we propose to exert multiple plasmonic resonant modes and their strong coupling using a metal-dielectric-metal (MDM) nanocavity that comprises an Au nanohole array (AuNHA), a TiO2 thin film and an Au reflector. Unlike common MDM structures, in addition to the Fabry-Pérot mode in the dielectric layer, AuNHA as the top layer is special because it excites the localized surface plasmon resonance (LSPR) mode in the Au nanoholes and launches the gap surface plasmon polariton (GSPP) mode in the Au reflector surface. The spatial field overlapping of the three resonance modes enables strong mode coupling by optimizing the TiO2 thickness, which leads to notably enhanced average IPCE (∼1.5%) and broadband photocurrent (170 μA·cm-2). This MDM structure would be useful for photochemistry and photovoltaics using sunlight. This journal is

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Enhancing plasmonic hot-carrier generation by strong coupling of multiple resonant modes

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GRF: Unidirectional Hot-Electron Injection Induced Out-Of-Plane Second-Harmonic Generation in Monolayer Transition Metal Dichalcogenides

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Enhancing plasmonic hot-carrier generation by strong coupling of multiple resonant modes

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GRF: Unidirectional Hot-Electron Injection Induced Out-Of-Plane Second-Harmonic Generation in Monolayer Transition Metal Dichalcogenides

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