Anomalous Coherence Length in Superconductors with Quantum Metric

Abstract

The coherence length is the fundamental length scale of superconductors which governs the sizes of Cooper pairs, vortices, Andreev bound states, and more. In BCS theory, the coherence length is BCS = vF/, where vF is the Fermi velocity and is the pairing gap. It is clear that increasing will shorten BCS. In this work, we show that the quantum metric, which is the real part of the quantum geometric tensor, gives rise to an anomalous contribution to the coherence length. Specifically, = BCS2 +qm2 for a superconductor where qm is the quantum metric contribution. In the flat-band limit, does not vanish but is bound below by qm. We demonstrate that under the uniform pairing condition, qm is controlled by the quantum metric of minimal trace in the flat-band limit. Physically, the Cooper pair size of a superconductor cannot be squeezed down to a size smaller than qm which is a fundamental length scale determined by the quantum geometry of the wave functions. Lastly, we compute the quantum metric contributions for the family of superconducting moir\'e graphene materials, demonstrating the significant role played by quantum metric effects in these narrow-band superconductors.