Imaging the Meissner effect and local superfluid stiffness in a graphene superconductor

Abstract

We report the observation of the Meissner effect in a rhombohedral graphene superconductor, realized via direct imaging of the static fringe magnetic field. In our few-micron sample, the onset of superconductivity manifests as a diamagnetic response that screens only 100 ppm of the applied magnetic field. Tracking the evolution of the resulting nanotesla-scale fields in real space allows us to observe the entry of superconducting vortices and map the local superfluid stiffness, s. Correlating fringe field signals from both Meissner screening and magnetically ordered states, we show that superconductivity onsets in the midst of a continuous quantum phase transition to a canted spin ferromagnet. Within the superconducting state, we find the temperature dependence of s to be incompatible with isotropic Bardeen-Cooper-Schrieffer theory and the zero-temperature stiffness s0 to be linearly proportional to Tc, constraining future theoretical models of superconductivity in this system.

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