Cavity-control of the Ginzburg-Landau stiffness in superconductors

Confining light around solids via cavities enhances the coupling between the electromagnetic fluctuations and the matter. We predict that in superconductors this cavity-enhanced coupling enables the control of the order-parameter stiffness, which governs key length scales such as the coherence length of Cooper pairs and the magnetic penetration depth. We explain this as a renormalization of the Cooper-pair mass caused by photon-mediated repulsive interactions between the electrons building the pair. The strength of this effect can be tuned via the length of the cavity and we estimate it to be sizable for cavities in the infrared range.