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

Molecular polaritons result from light-matter coupling between optical resonances and
molecular electronic or vibrational transitions. When the coupling is strong enough, new …

Molecular polaritons are the optical excitations which emerge when molecular transitions
interact strongly with confined electromagnetic fields. Increasing interest in the hybrid …

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 …

The demonstration of strong and ultrastrong coupling regimes of cavity QED with polyatomic
molecules has opened new routes to control chemical dynamics at the nanoscale. We show …

From the high vibrational dipolar strength offered by molecular liquids, we demonstrate that
a molecular vibration can be ultrastrongly coupled to multiple IR cavity modes, with Rabi …

The interaction of organic molecules and molecular aggregates with electromagnetic fields
that are strongly confined in nanoscale optical cavities has allowed the observation of exotic …

Organic microcavities can be engineered to reach exotic quantum regimes of strong and
ultrastrong light-matter coupling. However, the microscopic interpretation of their …

Hybridized polaritons are generated by simultaneously coupling two vibrational modes of
two different organic materials to the resonance of a low-loss infrared optical microcavity. A …

Vibrational strong coupling is an emerging method for modulation of ground-state molecular
properties. Spectroscopic information about the vibrational coupling state is essential for …