Pairing susceptibility in the weakly interacting multilayer Hubbard model evaluated by direct perturbative expansion

Abstract

We present a systematic study of the interaction, doping, and layer dependence of the dx2-y2-wave pairing susceptibility of the Hubbard model for a stacked 2D square lattice. We perform a multi-index perturbative expansion up to fourth-order to obtain coefficients in powers of the Hubbard U, the inter-layer V, and the pair-hopping J interactions. We evaluate the vertex diagrams that contribute to the pairing susceptibility for = 2,3, 4 layered models in the U-V-J interaction space. This provides unprecedented access to the pairing amplitudes, allowing us to identify the processes that enhance or reduce pairing. We distinguish pairing within the diagonal channel, Pd, and off-diagonal channel, Pd, and find that, in the absence of J, the qualitative behavior of the layered system is equivalent to the single-layer model. In the presence of J, we show that pairing is enhanced sublinearly with increasing and is primarily mediated by the Pd component and find which coefficients and diagram sets are responsible. Finally, we construct a generalized -dependent equation for Pd to speculate pairing beyond =4.