Nanometer-scale cavities for mid-infrared light based on graphene plasmons

Itai Epstein; David Alcaraz; Zhiqin Huang; Varun Varma Pusapati; Jean Paul Hugonin; Avinash Kumar; Xander Deputy; Tymofiy Khodkov; Tatiana G. Rappoport; Jin Yong Hong; Nuno M.R. Peres; Jing Kong; David R. Smith; Frank H.L. Koppens

doi:10.1117/12.2590037

Nanometer-scale cavities for mid-infrared light based on graphene plasmons

Itai Epstein, David Alcaraz, Zhiqin Huang, Varun Varma Pusapati, Jean Paul Hugonin, Avinash Kumar, Xander Deputy, Tymofiy Khodkov, Tatiana G. Rappoport, Jin Yong Hong, Nuno M.R. Peres, Jing Kong, David R. Smith, Frank H.L. Koppens

School of Electrical Engineering

Tel Aviv University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Acoustic-graphene-plasmons (AGPs) are highly confined electromagnetic modes, which carry extreme momentum and low loss in the Mid-infrared (MIR) to Terahertz (THz) spectra. They are therefore enablers of extremely strong light-matter interactions at these long wavelengths. However, owing to their large momentum they are also challenging to excite and detect. Here, we demonstrate a new way to excite AGPs that are confined to nanometric-scale cavities directly from the far-field, via localized graphene-plasmon-magnetic-resonators (GPMRs). This approach enables the efficient excitation of single AGP cavities, which are able to confine MIR light to record-breaking ultra-small mode-volumes, which are over a billion times smaller than their free-space volume.

Original language	English
Title of host publication	Optical Sensors 2021
Editors	Francesco Baldini, Jiri Homola, Robert A. Lieberman
Publisher	SPIE
ISBN (Electronic)	9781510643789
DOIs	https://doi.org/10.1117/12.2590037
State	Published - 2021
Event	Optical Sensors 2021 - Virtual, Online, Czech Republic Duration: 19 Apr 2021 → 23 Apr 2021

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	11772

Conference

Conference	Optical Sensors 2021
Country/Territory	Czech Republic
City	Virtual, Online
Period	19/04/21 → 23/04/21

Keywords

Acoustic graphene plasmons
MIR cavities
Magnetic resonance

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Computer Science Applications
Applied Mathematics
Electrical and Electronic Engineering

Access to Document

10.1117/12.2590037

Cite this

Epstein, I., Alcaraz, D., Huang, Z., Pusapati, V. V., Hugonin, J. P., Kumar, A., Deputy, X., Khodkov, T., Rappoport, T. G., Hong, J. Y., Peres, N. M. R., Kong, J., Smith, D. R., & Koppens, F. H. L. (2021). Nanometer-scale cavities for mid-infrared light based on graphene plasmons. In F. Baldini, J. Homola, & R. A. Lieberman (Eds.), Optical Sensors 2021 Article 117720Z (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11772). SPIE. https://doi.org/10.1117/12.2590037

@inproceedings{0cafb9cb347c416f9af0cfbb44547ef4,

title = "Nanometer-scale cavities for mid-infrared light based on graphene plasmons",

abstract = "Acoustic-graphene-plasmons (AGPs) are highly confined electromagnetic modes, which carry extreme momentum and low loss in the Mid-infrared (MIR) to Terahertz (THz) spectra. They are therefore enablers of extremely strong light-matter interactions at these long wavelengths. However, owing to their large momentum they are also challenging to excite and detect. Here, we demonstrate a new way to excite AGPs that are confined to nanometric-scale cavities directly from the far-field, via localized graphene-plasmon-magnetic-resonators (GPMRs). This approach enables the efficient excitation of single AGP cavities, which are able to confine MIR light to record-breaking ultra-small mode-volumes, which are over a billion times smaller than their free-space volume.",

keywords = "Acoustic graphene plasmons, MIR cavities, Magnetic resonance",

author = "Itai Epstein and David Alcaraz and Zhiqin Huang and Pusapati, \{Varun Varma\} and Hugonin, \{Jean Paul\} and Avinash Kumar and Xander Deputy and Tymofiy Khodkov and Rappoport, \{Tatiana G.\} and Hong, \{Jin Yong\} and Peres, \{Nuno M.R.\} and Jing Kong and Smith, \{David R.\} and Koppens, \{Frank H.L.\}",

note = "Publisher Copyright: {\textcopyright} 2021 SPIE.; Optical Sensors 2021 ; Conference date: 19-04-2021 Through 23-04-2021",

year = "2021",

doi = "10.1117/12.2590037",

language = "الإنجليزيّة",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Francesco Baldini and Jiri Homola and Lieberman, \{Robert A.\}",

booktitle = "Optical Sensors 2021",

address = "الولايات المتّحدة",

}

Epstein, I, Alcaraz, D, Huang, Z, Pusapati, VV, Hugonin, JP, Kumar, A, Deputy, X, Khodkov, T, Rappoport, TG, Hong, JY, Peres, NMR, Kong, J, Smith, DR & Koppens, FHL 2021, Nanometer-scale cavities for mid-infrared light based on graphene plasmons. in F Baldini, J Homola & RA Lieberman (eds), Optical Sensors 2021., 117720Z, Proceedings of SPIE - The International Society for Optical Engineering, vol. 11772, SPIE, Optical Sensors 2021, Virtual, Online, Czech Republic, 19/04/21. https://doi.org/10.1117/12.2590037

Nanometer-scale cavities for mid-infrared light based on graphene plasmons. / Epstein, Itai; Alcaraz, David; Huang, Zhiqin et al.
Optical Sensors 2021. ed. / Francesco Baldini; Jiri Homola; Robert A. Lieberman. SPIE, 2021. 117720Z (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11772).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Nanometer-scale cavities for mid-infrared light based on graphene plasmons

AU - Epstein, Itai

AU - Alcaraz, David

AU - Huang, Zhiqin

AU - Pusapati, Varun Varma

AU - Hugonin, Jean Paul

AU - Kumar, Avinash

AU - Deputy, Xander

AU - Khodkov, Tymofiy

AU - Rappoport, Tatiana G.

AU - Hong, Jin Yong

AU - Peres, Nuno M.R.

AU - Kong, Jing

AU - Smith, David R.

AU - Koppens, Frank H.L.

PY - 2021

Y1 - 2021

N2 - Acoustic-graphene-plasmons (AGPs) are highly confined electromagnetic modes, which carry extreme momentum and low loss in the Mid-infrared (MIR) to Terahertz (THz) spectra. They are therefore enablers of extremely strong light-matter interactions at these long wavelengths. However, owing to their large momentum they are also challenging to excite and detect. Here, we demonstrate a new way to excite AGPs that are confined to nanometric-scale cavities directly from the far-field, via localized graphene-plasmon-magnetic-resonators (GPMRs). This approach enables the efficient excitation of single AGP cavities, which are able to confine MIR light to record-breaking ultra-small mode-volumes, which are over a billion times smaller than their free-space volume.

AB - Acoustic-graphene-plasmons (AGPs) are highly confined electromagnetic modes, which carry extreme momentum and low loss in the Mid-infrared (MIR) to Terahertz (THz) spectra. They are therefore enablers of extremely strong light-matter interactions at these long wavelengths. However, owing to their large momentum they are also challenging to excite and detect. Here, we demonstrate a new way to excite AGPs that are confined to nanometric-scale cavities directly from the far-field, via localized graphene-plasmon-magnetic-resonators (GPMRs). This approach enables the efficient excitation of single AGP cavities, which are able to confine MIR light to record-breaking ultra-small mode-volumes, which are over a billion times smaller than their free-space volume.

KW - Acoustic graphene plasmons

KW - MIR cavities

KW - Magnetic resonance

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U2 - 10.1117/12.2590037

DO - 10.1117/12.2590037

M3 - منشور من مؤتمر

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Optical Sensors 2021

A2 - Baldini, Francesco

A2 - Homola, Jiri

A2 - Lieberman, Robert A.

PB - SPIE

T2 - Optical Sensors 2021

Y2 - 19 April 2021 through 23 April 2021

ER -

Nanometer-scale cavities for mid-infrared light based on graphene plasmons

Abstract

Publication series

Conference

Keywords

All Science Journal Classification (ASJC) codes

Access to Document

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