Classifying superconductivity in Moiré graphene superlattices

Several research groups have reported on the observation of superconductivity in bilayer graphene structures where single atomic layers of graphene are stacked and then twisted at angles θ forming Moiré superlattices. The characterization of the superconducting state in these 2D materials is an ongoing task. Here we investigate the pairing symmetry of bilayer graphene Moiré superlattices twisted at θ = 1.05°, 1.10° and 1.16° for carrier doping states varied in the range of n = (0.5 − 1.5) · 10(12) cm(−2) (where superconductivity can be realized) by analyzing the temperature dependence of the upper critical field B(c2)(T) and the self-field critical current J(c)(sf,T) within currently available models – all of which start from phonon-mediated BCS theory – for single- and two-band s−, d−, p− and d + id-wave gap symmetries. Extracted superconducting parameters show that only s-wave and a specific kind of p-wave symmetries are likely to be dominant in bilayer graphene Moiré superlattices. More experimental data is required to distinguish between the s- and remaining p-wave symmetries as well as the suspected two-band superconductivity in these 2D superlattices.