Magic-angle twisted trilayer graphene: Inhomogeneous twisted superconductor showing competing magnetic order

Twisted graphene systems form an exciting platform for studying the effects of strong electronic correlations arising from flat bands. Members of the twisted graphene family like magic-angle twisted bilayer graphene and magic-angle twisted trilayer graphene (MATTG) exhibit superconductivity. The origin of this unconventional superconductivity largely remains elusive. In our experiments with the MATTG, we observe evidence of MATTG being an inhomogeneous superconductor due to the presence of moiré solitons and twistons; creating weak links in the superconductor which behave like a network of Josephson junctions. We gather large statistics on the switching from the superconducting to the normal state - the switching distributions. Our experiments establish the technique of switching measurements as a novel way to probe these superconductors. These distributions are studied with the variation of temperature and in-plane magnetic field providing evidence of a competing magnetic order in the ground state. Additionally, a non-linear exponent extracted from DC I-V data allows us to infer the superfluid stiffness J_s in the system, providing a first experimental estimate of J_s in MATTG.