Long-Lived Phonon Polaritons in Hyperbolic Materials

Guangxin Ni; Alexander S. McLeod; Zhiyuan Sun; Joseph R. Matson; Chiu Fan Bowen Lo; Daniel A. Rhodes; Francesco L. Ruta; Samuel L. Moore; Rocco A. Vitalone; Ramon Cusco; Luis Artús; Lin Xiong; Cory R. Dean; James C. Hone; Andrew J. Millis; Michael M. Fogler; James H. Edgar; Joshua D. Caldwell; D. N. Basov

doi:10.1021/acs.nanolett.1c01562

Long-Lived Phonon Polaritons in Hyperbolic Materials

Guangxin Ni, Alexander S. McLeod, Zhiyuan Sun, Joseph R. Matson, Chiu Fan Bowen Lo, Daniel A. Rhodes, Francesco L. Ruta, Samuel L. Moore, Rocco A. Vitalone, Ramon Cusco, Luis Artús, Lin Xiong, Cory R. Dean, James C. Hone, Andrew J. Millis, Michael M. Fogler, James H. Edgar, Joshua D. Caldwell, D. N. Basov

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

37 Scopus citations

Abstract

Natural hyperbolic materials with dielectric permittivities of opposite signs along different principal axes can confine long-wavelength electromagnetic waves down to the nanoscale, well below the diffraction limit. Confined electromagnetic waves coupled to phonons in hyperbolic dielectrics including hexagonal boron nitride (hBN) and α-MoO₃are referred to as hyperbolic phonon polaritons (HPPs). HPP dissipation at ambient conditions is substantial, and its fundamental limits remain unexplored. Here, we exploit cryogenic nanoinfrared imaging to investigate propagating HPPs in isotopically pure hBN and naturally abundant α-MoO₃crystals. Close to liquid-nitrogen temperatures, losses for HPPs in isotopic hBN drop significantly, resulting in propagation lengths in excess of 8 μm, with lifetimes exceeding 5 ps, thereby surpassing prior reports on such highly confined polaritonic modes. Our nanoscale, temperature-dependent imaging reveals the relevance of acoustic phonons in HPP damping and will be instrumental in mitigating such losses for miniaturized mid-infrared technologies operating at liquid-nitrogen temperatures.

Original language	English (US)
Pages (from-to)	5767-5773
Number of pages	7
Journal	Nano letters
Volume	21
Issue number	13
DOIs	https://doi.org/10.1021/acs.nanolett.1c01562
State	Published - Jul 14 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021 American Chemical Society

Keywords

hyperbolic materials
nanoinfrared imaging
phonon polaritons
van der Waals heterostructures

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Ni, G., McLeod, A. S., Sun, Z., Matson, J. R., Lo, C. F. B., Rhodes, D. A., Ruta, F. L., Moore, S. L., Vitalone, R. A., Cusco, R., Artús, L., Xiong, L., Dean, C. R., Hone, J. C., Millis, A. J., Fogler, M. M., Edgar, J. H., Caldwell, J. D., & Basov, D. N. (2021). Long-Lived Phonon Polaritons in Hyperbolic Materials. Nano letters, 21(13), 5767-5773. https://doi.org/10.1021/acs.nanolett.1c01562

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abstract = "Natural hyperbolic materials with dielectric permittivities of opposite signs along different principal axes can confine long-wavelength electromagnetic waves down to the nanoscale, well below the diffraction limit. Confined electromagnetic waves coupled to phonons in hyperbolic dielectrics including hexagonal boron nitride (hBN) and α-MoO3are referred to as hyperbolic phonon polaritons (HPPs). HPP dissipation at ambient conditions is substantial, and its fundamental limits remain unexplored. Here, we exploit cryogenic nanoinfrared imaging to investigate propagating HPPs in isotopically pure hBN and naturally abundant α-MoO3crystals. Close to liquid-nitrogen temperatures, losses for HPPs in isotopic hBN drop significantly, resulting in propagation lengths in excess of 8 μm, with lifetimes exceeding 5 ps, thereby surpassing prior reports on such highly confined polaritonic modes. Our nanoscale, temperature-dependent imaging reveals the relevance of acoustic phonons in HPP damping and will be instrumental in mitigating such losses for miniaturized mid-infrared technologies operating at liquid-nitrogen temperatures.",

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AU - McLeod, Alexander S.

AU - Sun, Zhiyuan

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AU - Lo, Chiu Fan Bowen

AU - Rhodes, Daniel A.

AU - Ruta, Francesco L.

AU - Moore, Samuel L.

AU - Vitalone, Rocco A.

AU - Cusco, Ramon

AU - Artús, Luis

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AU - Dean, Cory R.

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AU - Millis, Andrew J.

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AU - Edgar, James H.

AU - Caldwell, Joshua D.

AU - Basov, D. N.

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N2 - Natural hyperbolic materials with dielectric permittivities of opposite signs along different principal axes can confine long-wavelength electromagnetic waves down to the nanoscale, well below the diffraction limit. Confined electromagnetic waves coupled to phonons in hyperbolic dielectrics including hexagonal boron nitride (hBN) and α-MoO3are referred to as hyperbolic phonon polaritons (HPPs). HPP dissipation at ambient conditions is substantial, and its fundamental limits remain unexplored. Here, we exploit cryogenic nanoinfrared imaging to investigate propagating HPPs in isotopically pure hBN and naturally abundant α-MoO3crystals. Close to liquid-nitrogen temperatures, losses for HPPs in isotopic hBN drop significantly, resulting in propagation lengths in excess of 8 μm, with lifetimes exceeding 5 ps, thereby surpassing prior reports on such highly confined polaritonic modes. Our nanoscale, temperature-dependent imaging reveals the relevance of acoustic phonons in HPP damping and will be instrumental in mitigating such losses for miniaturized mid-infrared technologies operating at liquid-nitrogen temperatures.

AB - Natural hyperbolic materials with dielectric permittivities of opposite signs along different principal axes can confine long-wavelength electromagnetic waves down to the nanoscale, well below the diffraction limit. Confined electromagnetic waves coupled to phonons in hyperbolic dielectrics including hexagonal boron nitride (hBN) and α-MoO3are referred to as hyperbolic phonon polaritons (HPPs). HPP dissipation at ambient conditions is substantial, and its fundamental limits remain unexplored. Here, we exploit cryogenic nanoinfrared imaging to investigate propagating HPPs in isotopically pure hBN and naturally abundant α-MoO3crystals. Close to liquid-nitrogen temperatures, losses for HPPs in isotopic hBN drop significantly, resulting in propagation lengths in excess of 8 μm, with lifetimes exceeding 5 ps, thereby surpassing prior reports on such highly confined polaritonic modes. Our nanoscale, temperature-dependent imaging reveals the relevance of acoustic phonons in HPP damping and will be instrumental in mitigating such losses for miniaturized mid-infrared technologies operating at liquid-nitrogen temperatures.

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Long-Lived Phonon Polaritons in Hyperbolic Materials

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