The quest for realizing novel fundamental physical effects and practical applications in
ambient conditions has led to tremendous interest in microcavity exciton polaritons working …

Semiconductors in all dimensionalities ranging from 0D quantum dots and molecules to 3D
bulk crystals support bound electron–hole pair quasiparticles termed excitons. Over the past …

Realizing lattices of exciton polariton condensates has been of much interest owing to the
potential of such systems to realize analogue Hamiltonian simulators and physical …

Quantum reservoir networks combine the intelligence of neural networks with the potential of
quantum computing in a single platform. This platform operates on the architecture of …

Exciton‐polaritons are half‐light, half‐matter bosonic quasiparticles formed by strong exciton–
photon coupling in semiconductor microcavities. These hybrid particles possess the strong …

Topological bound states in the continuum are confined wave-mechanical objects that offer
advantageous ways to enhance light–matter interactions in compact photonic devices. In …

Microcavities with embedded optically active materials allow to create exciton–polariton
condensates in the strong light–matter interaction regime. These condensates exhibit …

Strong coupling between light and matter in a microcavity can produce quasi‐particle states
termed cavity‐polaritons. In cavity architectures containing more than one excitonic species …

We have developed a simplified approach to fabricate high-reflectivity mirrors suitable for
applications in a strongly-coupled organic-semiconductor microcavity. Such mirrors are …

Polaritonic lattices offer a unique testbed for studying nonlinear driven-dissipative physics.
They show qualitative changes of their steady state as a function of system parameters …