Raman scattering of phonon polaritons under nanoscale confinement: the role of structure and environment

TL;DR

This paper investigates how nanoscale confinement influences Raman scattering in phonon polaritons, revealing structure- and environment-dependent behaviors that enable mid-infrared sensing and self-hybridization phenomena.

Contribution

It demonstrates that nanoscale confinement is essential for Raman scattering in phonon polaritons and explores the resulting hybridization effects and sensing applications.

Findings

Raman scattering depends on structure and environment in phonon polaritons.

Nanoscale confinement enables Raman scattering and self-hybridization.

Potential for mid-infrared refractive index sensing using visible-wavelength spectroscopy.

Abstract

Strong light-matter coupling gives rise to polaritons -- quasiparticles that combine both photonic and material characteristics. Here, we show that polar nanocrystals exhibit structure- and environment-dependent Raman scattering, enabled by their hybrid phonon polariton nature. Such dispersive behavior enables refractive index sensing in the mid-infrared range via visible-wavelength inelastic spectroscopy and draws parallels with molecular systems under vibrational strong coupling. Crucially, Raman scattering appears only under nanoscale confinement of phonon polaritons. For optimal structures, this leads to self-hybridization between localized phonon modes and surface phonon polaritons hosted by the same nanoparticle.