Effect of next-nearest neighbor hopping on the single-particle excitations
Abstract
In the half-filled one-orbital Hubbard model on a square lattice, we study the effect of next-nearest neighbor hopping on the single-particle spectral function at finite temperature using an exact-diagonalization + Monte-Carlo based approach to the simulation process. We find that the pseudogap-like dip, existing in the density of states in between the N\'eel temperature TN and a relatively higher temperature T*, is accompanied with a significant asymmetry in the hole- and particle-excitation energy along the high-symmetry directions as well as along the normal-state Fermi surface. On moving from (π/2, π/2) toward (π, 0) along the normal state Fermi surface, the hole-excitation energy increases, a behavior remarkably similar to what is observed in the d-wave state and pseudogap phase of high-Tc cuprates, whereas the particle-excitation energy decreases. The quasiparticle peak height is the largest near (π/2, π/2) whereas it is the smallest near (π, 0). These spectral features survive beyond TN. The temperature window TN T T* shrinks with an increase in the next-nearest neighbor hopping, which indicates that the next-nearest neighbor hopping may not be supportive to the pseudogap-like features.
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