Ising Superconductivity and Nematicity in Bernal Bilayer Graphene with Strong Spin Orbit Coupling

Superconductivity is a ubiquitous feature of graphite allotropes, having been observed in Bernal bilayers, rhombohedral trilayers, and a wide variety of angle-misaligned multilayers. Despite significant differences in the electronic structure across these systems, supporting the graphite layer on a WSe$_2$ substrate has been consistently observed to expand the range of superconductivity in carrier density and temperature. Here, we report the observation of two distinct superconducting states (denoted SC$_1$ and SC$_2$) in Bernal bilayer graphene with strong proximity-induced Ising spin-orbit coupling. Quantum oscillations show that while the normal state of SC$_1$ is consistent with the single-particle band structure, SC$_2$ emerges from a nematic normal state with broken rotational symmetry. Both superconductors are robust to in-plane magnetic fields, violating the paramagnetic limit as expected for spin-valley locked Ising superconductors. Our results show that the enhancement of superconductivity in WSe$_2$ supported graphite allotropes can be directly linked to Ising spin orbit coupling, which favors valley-balanced ground states with time-reversal symmetric Fermi surfaces friendly to superconducting pairing.