Fermi arcs and pseudogap phase in a minimal microscopic model of d-wave superconductivity
Abstract
We show conclusively that a pseudogap state can arise at T > Tc, for reasonable pairing interaction strength, from order parameter fluctuations in a two dimensional minimal model of d-wave superconductivity. The occurrence of the pseudogap requires neither strong correlation nor the presence of competing order. We study a model with attractive nearest neighbor interaction and establish our result using a combination of cluster based Monte Carlo for the order parameter field and a twisted-boundary scheme to compute the momentum-resolved spectral function. Apart from a dip in the density of states that characterizes the pseudogap, the momentum and frequency resolution on our effective lattice size 160 × 160 allows two major conclusions: (i)~at T < Tc, despite the presence of thermal phase fluctuations the superconductor has only nodal Fermi points while all non nodal points on the normal state Fermi surface show a two peak spectral function with a dip at ω =0, and (ii)~for T > Tc the Fermi points develops into arcs, characterized by a single quasiparticle peak, and the arcs connect up to recover the normal state Fermi surface at a temperature T* > Tc. We show the variation of Tc and T* with coupling strength and provide detailed spectral results at a coupling where T* 1.5Tc.
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