Electronic Structure, Magnetic and Pairing Tendencies of Alternating Single-layer Bilayer Stacking Nickelate La5Ni3O11 Under Pressure
Abstract
Nickelates have continued to surprise since their unconventional superconductivity was discovered. Recently, the layered nickelate La5Ni3O11 with hybrid single-layer and bilayer stacking showed superconductivity under high pressure. This compound combines features of La2NiO4 and La3Ni2O7, but its pairing mechanism remains to be understood. Motivated by this finding, here we report a comprehensive theoretical study of this system. Our density functional theory calculations reveal that the undistorted P4/mmm phase without pressure is unstable due to three distortion modes. Increasing pressure suppresses these modes and causes ``charge transfer'' between the single-layer and bilayer sublattices, leading to hole-doping in the single-layer blocks. Our random-phase approximation calculations indicate a leading dx2-y2-wave pairing state that arises from spin-fluctuation scattering between Fermi surface states mainly originating from the single-layer blocks and additional weaker contributions from the bilayer blocks. These spin-fluctuations could be detected by inelastic neutron scattering as a strong peak at q=(π, π). Our findings distinguish La5Ni3O11 from other nickelate superconductors discovered so far and the high-Tc cuprates. We also discuss both similarities and differences between La5Ni3O11 and other hybrid stacking nickelates.
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