Resonating-valence-bond superconductor from small Fermi surface in twisted bilayer graphene
Abstract
Mechanism of superconductivity in twisted bilayer graphene (TBG) remains one of the central problems in strongly correlated topological systems. The most intriguing question is about the nature of the normal state: is the Cooper pair formed from small Fermi surface or large Fermi surface? In this work we point out the possibility of a symmetric pseudogap metal with small hole pockets, dubbed as second Fermi liquid (sFL). In the sFL phase at $\nu=-2-x$, there is a two-component picture: two electrons mainly localize on the AA sites and form a paired singlet due to anti-Hund's coupling mediated by the optical phonon, while additional holes form small Fermi surfaces. The sFL phase corresponds to an intrinsically strongly interacting fixed point and violates the perturbative Luttinger theorem. We develop a unified framework to describe both a renormalized Fermi liquid (FL) and an sFL phase. We propose that the normal state of the TBG superconductor is the sFL phase, but it evolves toward the FL phase under increasing hole doping. The superconducting phase emerges from the sFL phase by transferring pairing of local moments to the mobile carriers. Interestingly, the superconducting gap can exhibit a nematic nodal $p_x$-pairing symmetry. This work provides, to our knowledge, the first unified theory that explains both the pseudogap metal above $T_c$ and the two-gap nematic superconductivity below it.