Minimal-size real-space d -wave pairing operator in CuO2 planes

Abstract

A novel minimal-size pairing operator $\Delta^{\dagger}_{D0}$ with $d$-wave symmetry in CuO$_2$ planes is introduced. This pairing operator creates on-site Cooper pairs at the four oxygens that surround a copper atom. Via the time evolution of $\Delta^{\dagger}_{D0}$, an additional inter-orbital pairing operator $\Delta^{\dagger}_{Dpd}$ with $d$-wave symmetry is generated that pairs fermions located in a Cu and its four surrounding O's. The subsequent time evolution of $\Delta^{\dagger}_{Dpd}$ generates an intra-orbital $d$-wave pairing operator $\Delta^{\dagger}_{Dpp}$ involving the four O atoms that surround a Cu, as well as the $d$-wave operator $\Delta^{\dagger}_D$ traditionally used in single-band models for cuprates. Because we recover the larger size operators extensively used in the three-orbital Hubbard model, we suggest that long-range order using the canonical extended operators occurs together with long-range order in the new minimal operators. However, our minimal $d$-wave operators could be more practical to study $d$-wave superconductivity because in the finite-size relatively small systems accessible to computational techniques it is easier to observe long-range order using local operators. Moreover, an effective model with the usual tight-binding hopping of the CuO$_2$ planes supplemented by an attractive potential $V$ in the $d$-wave channel is introduced. Using mean-field techniques we show that a paired ground state is stabilized for any finite value of $V$.