Litcius/Paper detail

Reversible Switching of Strong Light–Matter Coupling Using Spin-Crossover Molecular Materials

Lijun Zhang, Karl Ridier, Oleksandr Ye. Horniichuk, S. Calvez, Lionel Salmon, Gábor Molnár, Azzedine Bousseksou

2023The Journal of Physical Chemistry Letters11 citationsDOIOpen Access PDF

Abstract

The formation of hybrid light-matter states through the resonant interaction of confined electromagnetic fields with matter excitations has emerged as a fascinating tool for controlling quantum-mechanical states and then manipulating the functionalities and chemical reactivity landscape of molecular materials. Here we report the first observation of switchable strong light-matter coupling involving bistable spin-crossover molecules. Spectroscopic measurements, supported by transfer-matrix and coupled-oscillator simulations, reveal Rabi splitting values of up to 550 meV, which at 15% of the molecular excitation energy enter the regime of ultrastrong coupling. We find that the thermally induced switching of molecules between their low-spin and high-spin states allows fine control of the light-matter hybridization strength, offering the appealing possibility of reversible switching between the ultrastrong- and weak-coupling regimes within a single photonic structure. Through this work, we show that spin-crossover molecular compounds constitute a promising class of active nanomaterials in the burgeoning context of tunable polaritonic devices and polaritonic chemistry.

Topics & Concepts

BistabilityContext (archaeology)Coupling (piping)Molecular switchState of matterDephasingPhysicsSpin (aerodynamics)PhotonicsCondensed matter physicsSpin crossoverExcitationMoleculeChemical physicsMaterials scienceOptoelectronicsQuantum mechanicsThermodynamicsPaleontologyMetallurgyBiologyStrong Light-Matter InteractionsQuantum and electron transport phenomenaPlasmonic and Surface Plasmon Research