The interaction between molecular electronic transitions and electromagnetic fields can be
enlarged to the point where distinct hybrid light–matter states, polaritons, emerge. The …

It is possible to modify the chemical and physical properties of molecules, not only through
chemical modifications but also by coupling molecules strongly to light. More intriguingly …

Conspectus The notion that light and matter states can be hybridized the way s and p
orbitals are mixed is a concept that is not familiar to most chemists and material scientists …

This is a tutorial-style introduction to the field of molecular polaritons. We describe the basic
physical principles and consequences of strong light–matter coupling common to molecular …

In this review we look at the concepts and state-of-the-art concerning the strong coupling of
surface plasmon-polariton modes to states associated with quantum emitters such as …

Much effort over the past decades has been focused on improving carrier mobility in organic
thin-film transistors by optimizing the organization of the material or the device architecture …

The optical hybridization of the electronic states in strongly coupled molecule–cavity
systems have revealed unique properties, such as lasing, room temperature polariton …

We present direct evidence of enhanced non‐radiative energy transfer between two J‐
aggregated cyanine dyes strongly coupled to the vacuum field of a cavity. Excitation …

Strong coupling between light and matter leads to the spontaneous formation of hybrid light–
matter states, having different energies than the uncoupled states. This opens up for new …

Vibrational strong coupling offers newfound potential to affect chemical processes and
represents a wholly new approach to catalysis. While this presents extraordinary …