Resolving resonance effects in the theory of single particle photothermal imaging (2103.01494v2)

Abstract: Photothermal spectroscopy and microscopy provides a route to measure the spectral and spatial properties of individual nanoscopic absorbers, independent from scattering, extinction, and emission. The approach relies upon use of two light sources, one that resonantly excites and heats the target and its surrounding environment and a second off-resonant probe that scatters from the resulting volume of thermally modified refractive index. Over the past twenty years, considerable effort has been extended to apply photothermal methods to detect, spatially resolve, and perform absorption spectroscopy on single non-emissive molecules and other absorbers like plasmonic nanoparticles at room temperature conditions. Companion theoretical models have been developed to interpret these experimental advances, yet it is not clear how they are related to each other nor how the effects of lock-in detection modify the theory. For larger target systems that host their own intrinsic scattering resonances as well as for background media that do not instantaneously thermalize with the absorbing target, additional dependencies arise that are yet to be explored theoretically. The aim of this Perspective is to overview the theory of photothermal spectroscopy and microscopy and present a unifying theoretical approach that recovers past models in certain limits while explicitly including the effects of target scattering resonances, thermal and optical retardation, and lock-in detection. Focus is made on plasmonic particles to interpret the photothermal signal, yet all results are applicable equally to individual molecules or nanoparticle absorbers. Consequently, we expect this review to provide a useful foundation for the understanding of photothermal measurements independent of target identity.