The role of the plasmon in interfacial charge transfer

Behnaz Ostovar; Stephen A. Lee; Arshad Mehmood; Kieran Farrell; Emily K. Searles; Briley Bourgeois; Wei Yi Chiang; Anastasiia Misiura; Niklas Gross; Alexander Al-Zubeidi; Jennifer A. Dionne; Christy F. Landes; Martin Zanni; Benjamin G. Levine; Stephan Link

doi:10.1126/sciadv.adp3353

The role of the plasmon in interfacial charge transfer

Behnaz Ostovar, Stephen A. Lee, Arshad Mehmood, Kieran Farrell, Emily K. Searles, Briley Bourgeois, Wei Yi Chiang, Anastasiia Misiura, Niklas Gross, Alexander Al-Zubeidi, Jennifer A. Dionne, Christy F. Landes, Martin Zanni, Benjamin G. Levine, Stephan Link

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

Abstract

The lack of a detailed mechanistic understanding for plasmon-mediated charge transfer at metal-semiconductor interfaces severely limits the design of efficient photovoltaic and photocatalytic devices. A major remaining question is the relative contribution from indirect transfer of hot electrons generated by plasmon decay in the metal to the semiconductor compared to direct metal-to- semiconductor interfacial charge transfer. Here, we demonstrate an overall electron transfer efficiency of 44 ± 3% from gold nanorods to titanium oxide shells when excited on resonance. We prove that half of it originates from direct interfacial charge transfer mediated specifically by exciting the plasmon. We are able to distinguish between direct and indirect pathways through multimodal frequency-resolved approach measuring the homogeneous plasmon linewidth by single-particle scattering spectroscopy and time-resolved transient absorption spectroscopy with variable pump wavelengths. Our results signify that the direct plasmon-induced charge transfer pathway is a promising way to improve hot carrier extraction efficiency by circumventing metal intrinsic decay that results mainly in nonspecific heating.

Original language	English (US)
Article number	adp3353
Journal	Science Advances
Volume	10
Issue number	27
DOIs	https://doi.org/10.1126/sciadv.adp3353
State	Published - Jul 2024

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@article{4191184a6cf24dd9b75039dbe4f1a7c2,

title = "The role of the plasmon in interfacial charge transfer",

abstract = "The lack of a detailed mechanistic understanding for plasmon-mediated charge transfer at metal-semiconductor interfaces severely limits the design of efficient photovoltaic and photocatalytic devices. A major remaining question is the relative contribution from indirect transfer of hot electrons generated by plasmon decay in the metal to the semiconductor compared to direct metal-to- semiconductor interfacial charge transfer. Here, we demonstrate an overall electron transfer efficiency of 44 ± 3% from gold nanorods to titanium oxide shells when excited on resonance. We prove that half of it originates from direct interfacial charge transfer mediated specifically by exciting the plasmon. We are able to distinguish between direct and indirect pathways through multimodal frequency-resolved approach measuring the homogeneous plasmon linewidth by single-particle scattering spectroscopy and time-resolved transient absorption spectroscopy with variable pump wavelengths. Our results signify that the direct plasmon-induced charge transfer pathway is a promising way to improve hot carrier extraction efficiency by circumventing metal intrinsic decay that results mainly in nonspecific heating.",

author = "Behnaz Ostovar and Lee, {Stephen A.} and Arshad Mehmood and Kieran Farrell and Searles, {Emily K.} and Briley Bourgeois and Chiang, {Wei Yi} and Anastasiia Misiura and Niklas Gross and Alexander Al-Zubeidi and Dionne, {Jennifer A.} and Landes, {Christy F.} and Martin Zanni and Levine, {Benjamin G.} and Stephan Link",

note = "Acknowledgments: this work was conducted in part using resources of the Shared equipment Authority at Rice University. B.G.l. and A.M. gratefully acknowledge support from the institute for Advanced computational Science. Funding: this work was supported by the nSF center for Adopting Flaws as Features grant che-2413590 (J.A.d., c.F.l., M.Z., B.G.l., and S.l.), charles W. duncan, Jr.-Welch chair in chemistry c-0002 (S.l.), nSF dMR-2225592 (S.l.), and Robert A. Welch Foundation c-1787 (c.F.l.). Author contributions: conceptualization: B.O., S.A.l., and S.l. investigation: B.O., S.A.l., A.M., K.F., e.K.S., B.B., W.-Y.c., A.M., n.G., and AA. visualization: B.O. and S.A.l. Supervision: J.A.d., c.F.l., M.Z., B.G.l., and S.l. Writing: B.O., S.A.l., c.F.l., and S.l. Competing interests: the authors declare that they have no competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. the software written to perform Persson\u2019s model calculations is available for free download at https://zenodo.org/ doi/10.5281/zenodo.11243156. it is requested that future users of this software cite the present paper.",

year = "2024",

month = jul,

doi = "10.1126/sciadv.adp3353",

language = "English (US)",

volume = "10",

journal = "Science Advances",

issn = "2375-2548",

publisher = "American Association for the Advancement of Science",

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T1 - The role of the plasmon in interfacial charge transfer

AU - Ostovar, Behnaz

AU - Lee, Stephen A.

AU - Mehmood, Arshad

AU - Farrell, Kieran

AU - Searles, Emily K.

AU - Bourgeois, Briley

AU - Chiang, Wei Yi

AU - Misiura, Anastasiia

AU - Gross, Niklas

AU - Al-Zubeidi, Alexander

AU - Dionne, Jennifer A.

AU - Landes, Christy F.

AU - Zanni, Martin

AU - Levine, Benjamin G.

AU - Link, Stephan

N1 - Acknowledgments: this work was conducted in part using resources of the Shared equipment Authority at Rice University. B.G.l. and A.M. gratefully acknowledge support from the institute for Advanced computational Science. Funding: this work was supported by the nSF center for Adopting Flaws as Features grant che-2413590 (J.A.d., c.F.l., M.Z., B.G.l., and S.l.), charles W. duncan, Jr.-Welch chair in chemistry c-0002 (S.l.), nSF dMR-2225592 (S.l.), and Robert A. Welch Foundation c-1787 (c.F.l.). Author contributions: conceptualization: B.O., S.A.l., and S.l. investigation: B.O., S.A.l., A.M., K.F., e.K.S., B.B., W.-Y.c., A.M., n.G., and AA. visualization: B.O. and S.A.l. Supervision: J.A.d., c.F.l., M.Z., B.G.l., and S.l. Writing: B.O., S.A.l., c.F.l., and S.l. Competing interests: the authors declare that they have no competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. the software written to perform Persson\u2019s model calculations is available for free download at https://zenodo.org/ doi/10.5281/zenodo.11243156. it is requested that future users of this software cite the present paper.

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N2 - The lack of a detailed mechanistic understanding for plasmon-mediated charge transfer at metal-semiconductor interfaces severely limits the design of efficient photovoltaic and photocatalytic devices. A major remaining question is the relative contribution from indirect transfer of hot electrons generated by plasmon decay in the metal to the semiconductor compared to direct metal-to- semiconductor interfacial charge transfer. Here, we demonstrate an overall electron transfer efficiency of 44 ± 3% from gold nanorods to titanium oxide shells when excited on resonance. We prove that half of it originates from direct interfacial charge transfer mediated specifically by exciting the plasmon. We are able to distinguish between direct and indirect pathways through multimodal frequency-resolved approach measuring the homogeneous plasmon linewidth by single-particle scattering spectroscopy and time-resolved transient absorption spectroscopy with variable pump wavelengths. Our results signify that the direct plasmon-induced charge transfer pathway is a promising way to improve hot carrier extraction efficiency by circumventing metal intrinsic decay that results mainly in nonspecific heating.

AB - The lack of a detailed mechanistic understanding for plasmon-mediated charge transfer at metal-semiconductor interfaces severely limits the design of efficient photovoltaic and photocatalytic devices. A major remaining question is the relative contribution from indirect transfer of hot electrons generated by plasmon decay in the metal to the semiconductor compared to direct metal-to- semiconductor interfacial charge transfer. Here, we demonstrate an overall electron transfer efficiency of 44 ± 3% from gold nanorods to titanium oxide shells when excited on resonance. We prove that half of it originates from direct interfacial charge transfer mediated specifically by exciting the plasmon. We are able to distinguish between direct and indirect pathways through multimodal frequency-resolved approach measuring the homogeneous plasmon linewidth by single-particle scattering spectroscopy and time-resolved transient absorption spectroscopy with variable pump wavelengths. Our results signify that the direct plasmon-induced charge transfer pathway is a promising way to improve hot carrier extraction efficiency by circumventing metal intrinsic decay that results mainly in nonspecific heating.

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The role of the plasmon in interfacial charge transfer

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