Local environment influence on mid-infrared photothermal contrast

Abstract

Mid-infrared (MIR) photothermal microscopy and spectroscopy represents a new, ultrasensitive, superresolution infrared absorption technique. The origin of its signal contrast is complex, containing competing contributions from photothermal-induced changes to specimen refractive indices and volumes as well as those of the local environment. In this study, we investigate the interplay between abovementioned thermo-optic/thermal expansion contributions to observed contrast in MIR photothermal microscopy images and spectra. This entails size-dependent measurements on individual polystyrene and polymethylmethacrylate nanoparticles with radii below 100 nm and as low as 25 nm. From this, we establish that sizable photothermal contrast arises from the interference between light scattered from a specimen’s local dielectric medium and backreflected light from an air/substrate interface. The model is corroborated by the observation of a predicted, small nanoparticle size crossover in signal contrast between particles embedded in air versus a dielectric medium with a refractive index greater than one.