Cavity control of quantum matter may offer new ways to study and manipulate many-body
systems. A particularly appealing idea is to use cavities to enhance superconductivity …

Pump-probe experiments have suggested the possibility to control electronic correlations by
driving infrared-active (IR-active) phonons with resonant midinfrared laser pulses. In this …

We discuss how complex-oxide heterostructures that include high-T c superconducting
cuprates can be used to realize an array of submillimeter cavities that support Josephson …

The emergent field of cavity quantum materials bridges collective many-body phenomena in
solid state platforms with strong light–matter coupling in cavity quantum electrodynamics …

We review some recent advances in the use of optical fields at terahertz frequencies to drive
the lattice of complex materials. We will focus on the control of low energy collective …

The hallmark of superconductivity is the rigidity of the quantum-mechanical phase of
electrons, responsible for superfluid behavior and Meissner effect. The strength of the phase …

We analyze the magnetic dipole coupling of an ensemble of spins to a superconducting
microwave stripline structure, incorporating a Josephson junction based transmon qubit. We …

Quantum-mechanical phenomena underpin the behaviour of quantum materials at the
microscopic level. The description of several essential properties of these materials …

We reanalyze the issue whether the resonance peak observed in neutron scattering
experiments on the cuprates is an exciton, a π-resonance, or a magnetic plasmon. We …

The light-matter interaction can be utilized to qualitatively alter physical properties of
materials. Recent theoretical and experimental studies have explored this possibility of …