Studies of hot photoluminescence in plasmonically coupled silicon via variable energy excitation and temperature-dependent spectroscopy

Carlos O. Aspetti; Chang Hee Cho; Rahul Agarwal; Ritesh Agarwal

doi:10.1021/nl502606q

Studies of hot photoluminescence in plasmonically coupled silicon via variable energy excitation and temperature-dependent spectroscopy

Carlos O. Aspetti, Chang Hee Cho, Rahul Agarwal, Ritesh Agarwal

Department of Physics and Chemistry

University of Pennsylvania

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

15 Scopus citations

Abstract

By integrating silicon nanowires (∼150 nm diameter, 20 μm length) with an ω-shaped plasmonic nanocavity, we are able to generate broadband visible luminescence, which is induced by high order hybrid nanocavity-surface plasmon modes. The nature of this super bandgap emission is explored via photoluminescence spectroscopy studies performed with variable laser excitation energies (1.959 to 2.708 eV) and finite difference time domain simulations. Furthermore, temperature-dependent photoluminescence spectroscopy shows that the observed emission corresponds to radiative recombination of unthermalized (hot) carriers as opposed to a resonant Raman process.

Original language	English
Pages (from-to)	5413-5422
Number of pages	10
Journal	Nano Letters
Volume	14
Issue number	9
DOIs	https://doi.org/10.1021/nl502606q
State	Published - 10 Sep 2014

Bibliographical note

Publisher Copyright:
© 2014 American Chemical Society.

Keywords

Silicon
luminescence
photonics
plasmonics

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10.1021/nl502606q

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title = "Studies of hot photoluminescence in plasmonically coupled silicon via variable energy excitation and temperature-dependent spectroscopy",

abstract = "By integrating silicon nanowires (∼150 nm diameter, 20 μm length) with an ω-shaped plasmonic nanocavity, we are able to generate broadband visible luminescence, which is induced by high order hybrid nanocavity-surface plasmon modes. The nature of this super bandgap emission is explored via photoluminescence spectroscopy studies performed with variable laser excitation energies (1.959 to 2.708 eV) and finite difference time domain simulations. Furthermore, temperature-dependent photoluminescence spectroscopy shows that the observed emission corresponds to radiative recombination of unthermalized (hot) carriers as opposed to a resonant Raman process.",

keywords = "Silicon, luminescence, photonics, plasmonics",

author = "Aspetti, {Carlos O.} and Cho, {Chang Hee} and Rahul Agarwal and Ritesh Agarwal",

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doi = "10.1021/nl502606q",

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T1 - Studies of hot photoluminescence in plasmonically coupled silicon via variable energy excitation and temperature-dependent spectroscopy

AU - Aspetti, Carlos O.

AU - Cho, Chang Hee

AU - Agarwal, Rahul

AU - Agarwal, Ritesh

PY - 2014/9/10

Y1 - 2014/9/10

N2 - By integrating silicon nanowires (∼150 nm diameter, 20 μm length) with an ω-shaped plasmonic nanocavity, we are able to generate broadband visible luminescence, which is induced by high order hybrid nanocavity-surface plasmon modes. The nature of this super bandgap emission is explored via photoluminescence spectroscopy studies performed with variable laser excitation energies (1.959 to 2.708 eV) and finite difference time domain simulations. Furthermore, temperature-dependent photoluminescence spectroscopy shows that the observed emission corresponds to radiative recombination of unthermalized (hot) carriers as opposed to a resonant Raman process.

AB - By integrating silicon nanowires (∼150 nm diameter, 20 μm length) with an ω-shaped plasmonic nanocavity, we are able to generate broadband visible luminescence, which is induced by high order hybrid nanocavity-surface plasmon modes. The nature of this super bandgap emission is explored via photoluminescence spectroscopy studies performed with variable laser excitation energies (1.959 to 2.708 eV) and finite difference time domain simulations. Furthermore, temperature-dependent photoluminescence spectroscopy shows that the observed emission corresponds to radiative recombination of unthermalized (hot) carriers as opposed to a resonant Raman process.

KW - Silicon

KW - luminescence

KW - photonics

KW - plasmonics

UR - http://www.scopus.com/inward/record.url?scp=84908648841&partnerID=8YFLogxK

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M3 - Article

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SN - 1530-6984

VL - 14

SP - 5413

EP - 5422

JO - Nano Letters

JF - Nano Letters

IS - 9

ER -

Studies of hot photoluminescence in plasmonically coupled silicon via variable energy excitation and temperature-dependent spectroscopy

Abstract

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