Intertwined orders of ultracold fermions loaded in two-dimensional optical lattices

The generic quantum phase diagram of repulsively interacting spin-1/2 ultracold atoms, moving in a two-dimensional optical lattice, is investigated by means of unbiased energy minimizations with symmetry-adapted unrestricted wavefunctions. In the strongly correlated regime, we highlight the intertwining of spin-, charge-, and pair-density waves embedded in a uniform d-wave superfluid background. As the lattice filling increases, this phase emerges from homogenous states exhibiting spiral magnetism and evolves towards a doped antiferromagnet. A concomitant enhancement of long-ranged d-wave pairing correlations is also found. Nevertheless, superfluidity is suppressed when the charge period and the inverse of the hole doping from half-filling are commensurate. Numerical tests of the approach are carried out, too.