Abstract
Strong coupling between various kinds of material excitations and optical modes has recently shown potential to modify chemical reaction rates in both excited and ground states. The ground-state modification in chemical reaction rates has usually been reported by coupling a vibrational mode of an organic molecule to the vacuum field of an external optical cavity, such as a planar Fabry-Pérot microcavity made of two metallic mirrors. However, using an external cavity to form polaritonic states might (i) limit the scope of possible applications of such systems and (ii) might be unnecessary. Here, we highlight the possibility of using optical modes sustained by materials themselves to self-couple to their own electronic or vibrational resonances. By tracing the roots of the corresponding dispersion relations in the complex frequency plane, we show that electronic and vibrational polaritons are natural eigenstates of bulk and nanostructured resonant materials that require no external cavity. Several concrete examples such as a slab of the excitonic material and a spherical water droplet in vacuum are shown to reach the regime of such cavity-free self-strong coupling. The abundance of cavity-free polaritons in simple and natural structures points at their relevance and potential practical importance for the emerging field of polaritonic chemistry, exciton transport, and modified material properties.
Highlights
Strong coupling is a distinct regime of light–matter interactions realized when resonant optical modes and material excitations exchange energy faster than they lose it to the environment
We have shown that polaritonic states are natural and ubiquitous to bulk materials and nanostructures that can be described by a generic Lorentz resonance(s)
All observations relevant to the cavity polaritons could just be applicable to the cavity-free polaritons presented here, provided that it is the polaritonic nature of those modes that is responsible for chemistry and material science modifications
Summary
Strong coupling is a distinct regime of light–matter interactions realized when resonant optical modes and material excitations (electronic, vibrational, etc.) exchange energy faster than they lose it to the environment. This fast energy exchange gives rise to new quasiparticles: polaritons.. Activated ground-state chemical reactions in the vibrational strong coupling (VSC) regime seem to be more controversial. In this case, just a few experimental reports exist, and there is far less conclusive agreement with theory.
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