Collective Phonon-Polaritonic Modes in Silicon Carbide Subarrays

Guanyu Lu; Christopher R. Gubbin; J. Ryan Nolen; Thomas G. Folland; Katja Diaz-Granados; Ivan I. Kravchenko; Joseph A. Spencer; Marko J. Tadjer; Orest J. Glembocki; Simone De Liberato; Joshua D. Caldwell

doi:10.1021/acsnano.1c08557

Collective Phonon-Polaritonic Modes in Silicon Carbide Subarrays

Guanyu Lu, Christopher R. Gubbin, J. Ryan Nolen, Thomas G. Folland, Katja Diaz-Granados, Ivan I. Kravchenko, Joseph A. Spencer, Marko J. Tadjer, Orest J. Glembocki, Simone De Liberato, Joshua D. Caldwell

Nanofabrication Research Laboratory

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

7 Scopus citations

Abstract

Localized surface phonon polaritons (LSPhPs) can be implemented to engineer light-matter interactions through nanoscale patterning for a range of midinfrared application spaces. However, the polar material systems studied to date have mainly focused on simple designs featuring a single element in the periodic unit cell. Increasing the complexity of the unit cell can serve to modify the resonant near-fields and intra- and inter-unit-cell coupling as well as to dictate spectral tuning in the far-field. In this work, we exploit more complicated unit-cell structures to realize LSPhP modes with additional degrees of design freedom, which are largely unexplored. Collectively excited LSPhP modes with distinctly symmetric and antisymmetric near-fields are supported in these subarray designs, which are based on nanopillars that are scaled by the number of subarray elements to ensure a constant unit-cell size. Moreover, we observe an anomalous mode-matching of the collective symmetric mode in our fabricated subarrays that is robust to changing numbers of pillars within the subarrays as well as to defects intentionally introduced in the form of missing pillars. This work therefore illustrates the hierarchical design of tailored LSPhP resonances and modal near-field profiles simultaneously for a variety of IR applications such as surface-enhanced spectroscopies and biochemical sensing.

Original language	English
Pages (from-to)	963-973
Number of pages	11
Journal	ACS Nano
Volume	16
Issue number	1
DOIs	https://doi.org/10.1021/acsnano.1c08557
State	Published - Jan 25 2022

Funding

Funding for G.L. was provided through an STTR program provided by the National Science Foundation, Division of Industrial Innovation and Partnerships (IIP) (Award No. 2014798). A portion of this research was conducted at the Vanderbilt Institute of Nanoscale Science and Engineering. S.D.L. was supported by a Royal Society Research fellowship (Grant no. URF\R\180002) and the Philip Leverhulme prize. C.R.G. was supported by the Royal Society (Grant no. RGF\EA\181001) and a Research Grant of the Leverhulme Trust (Grant No. RPG-2019-174). J.R.N. and J.D.C. were supported by Office of Naval Research Grant N00014-18-12107. Research at the Naval Research Laboratory was supported by the Office of Naval Research. A portion of this research was conducted at the Center for Nanophase Materials Sciences, which is a DOE Office of Science User Facility.

Keywords

localized surface phonon polariton
midinfrared
monopolar resonance
strong coupling
unit cell

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10.1021/acsnano.1c08557

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abstract = "Localized surface phonon polaritons (LSPhPs) can be implemented to engineer light-matter interactions through nanoscale patterning for a range of midinfrared application spaces. However, the polar material systems studied to date have mainly focused on simple designs featuring a single element in the periodic unit cell. Increasing the complexity of the unit cell can serve to modify the resonant near-fields and intra- and inter-unit-cell coupling as well as to dictate spectral tuning in the far-field. In this work, we exploit more complicated unit-cell structures to realize LSPhP modes with additional degrees of design freedom, which are largely unexplored. Collectively excited LSPhP modes with distinctly symmetric and antisymmetric near-fields are supported in these subarray designs, which are based on nanopillars that are scaled by the number of subarray elements to ensure a constant unit-cell size. Moreover, we observe an anomalous mode-matching of the collective symmetric mode in our fabricated subarrays that is robust to changing numbers of pillars within the subarrays as well as to defects intentionally introduced in the form of missing pillars. This work therefore illustrates the hierarchical design of tailored LSPhP resonances and modal near-field profiles simultaneously for a variety of IR applications such as surface-enhanced spectroscopies and biochemical sensing.",

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Collective Phonon-Polaritonic Modes in Silicon Carbide Subarrays

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