Kinetic Inductance, Quantum Geometry, and Superconductivity in Magic-Angle Twisted Bilayer Graphene

The physics of superconductivity in magic-angle twisted bilayer graphene (MATBG) is a topic of keen interest in moir\'e systems research, and it may provide insight into the pairing mechanism of other strongly correlated materials such as high-$T_{\mathrm{c}}$ superconductors. Here, we use DC-transport and microwave circuit quantum electrodynamics (cQED) to measure directly the superfluid stiffness of superconducting MATBG via its kinetic inductance. We find the superfluid stiffness to be much larger than expected from conventional single-band Fermi liquid theory; rather, it aligns well with theory involving quantum geometric effects that are dominant at the magic angle. The temperature dependence of the superfluid stiffness exhibits a power-law behavior, which contraindicates an isotropic BCS model; instead, the extracted power-law exponents indicate an anisotropic superconducting gap, whether interpreted using the conventional anisotropic BCS model or a quantum geometric theory of flat-band superconductivity. Moreover, the quadratic dependence of the stiffness on both DC and microwave current is consistent with Ginzburg-Landau theory. Taken together, these findings strongly suggest a connection between quantum geometry, superfluid stiffness, and unconventional superconductivity in MATBG. Finally, the combined DC-microwave measurement platform used here is applicable to the investigation of other atomically thin superconductors.