Nonlinear signal enhancement of strongly-coupled molecules in pump-probe experiments

TL;DR

This paper investigates how non-resonant pump-probe configurations can enhance signals from strongly-coupled molecules while reducing optical artifacts, compared to resonant schemes.

Contribution

It quantifies the contributions of coupled and uncoupled molecules in different pump-probe setups, highlighting the advantages of non-resonant schemes.

Findings

Non-resonant schemes retain high sensitivity to strongly-coupled molecules.

Resonant schemes maximize selectivity for strongly-coupled molecules.

Non-resonant schemes are less susceptible to optical artifacts.

Abstract

Nonlinear spectroscopy is widely used to study the transient dynamics of molecules under strong light-matter coupling, though it remains unclear to what extent uncoupled intracavity molecules obscure signals from the strongly-coupled species of interest. Pump or probe fields resonant in the strongly-coupled spectral region will preferentially interact with cavity-coupled molecules, but can exhibit severe optical artifacts due to wave interference in the cavity. On the other hand, non-resonant pump or probe fields having wavelengths at which the cavity mirrors are highly transmissive propagate as traveling waves along the cavity axis, interacting with both coupled and uncoupled intracavity molecules. Here, we quantify the contributions of signals from strongly-coupled and uncoupled populations in simulated experiments with different resonant and non-resonant pump-probe configurations. We find that while resonant schemes maximize selectivity for the signals of strongly-coupled molecules, non-resonant schemes retain surprisingly high sensitivity to these signals while remaining less susceptible to optical artifacts.