Zigzag chain structure transition and orbital fluctuations in Ni-based superconductors

Abstract

We investigate the electronic state and structure transition of BaNi2As2, which shows a similar superconducting phase diagram as Fe-based superconductors. We construct the ten-orbital tight-binding model for BaNi2As2 by using the maximally localized Wannier function method. The Coulomb and quadrupole-quadrupole interactions are treated within the random-phase approximation. We obtain the strong developments of charge quadrupole susceptibilities driven by the in-plane and out-of-plane oscillations of Ni ions. The largest susceptibility is either OX2-Y2-quadrupole susceptibility at q = (pi, 0, pi) or OXZ(YZ)-quadrupole susceptibility at q = (pi, pi, pi), depending on the level splitting between dX2-Y2 and dXZ(YZ). These antiferro-quadrupole fluctuations would then be the origin of the strong coupling superconductivity in Ni-based superconductors. Also, we propose that the antiferro-quadrupole OX2-Y2 order with q = (pi, 0, pi) is the origin of the zigzag chain structure reported in experiments. We identify similarities and differences between Ni- and Fe-based superconductors.