Molecules are the building blocks of all of nature's functional components, serving as the
machinery that captures, stores and releases energy or converts it into useful work …

Organic polaritonics has emerged as a captivating interdisciplinary field that marries the
complexities of organic photophysics with the fundamental principles of quantum optics. By …

Exciton transport can be enhanced in the strong coupling regime where excitons hybridize
with confined light modes to form polaritons. Because polaritons have group velocity, their …

Dynamic metasurfaces have emerged as a disruptive change in the way the response of
optical systems can be tailored by combining the flexibility of flat optics in spatially …

Halide perovskites have emerged as promising materials for a wide variety of optoelectronic
applications, including solar cells, light‐emitting devices, photodetectors, and quantum …

The observation that materials can change their properties when placed inside or near an
optical resonator has sparked a fervid interest in understanding the effects of strong light …

Monolayers of transition metal dichalcogenides (TMDCs) are direct-gap semiconductors
with strong light–matter interactions featuring tightly bound excitons, while plasmonic …

Recent experiments have shown that exciton transport can be significantly enhanced
through hybridization with confined photonic modes in a cavity. The light-matter …

Spatial manipulation of excitonic quasiparticles, such as neutral excitons, charged excitons,
and interlayer excitons, in two-dimensional semiconductors offers unique capabilities for a …

Advances in optical measurements enable precise tracking of cavity polariton dynamics with
exceptional spatiotemporal resolution. Building on these developments, we present a …