Pressure induced redistribution of oxygen hole states in La4Ni3O10

Abstract

Using density functional calculations and multi-orbital, multi-atom cluster exact diagonalization that includes local exchange and Coulomb interactions, we explored the local low-energy electronic states of trilayer La4Ni3O10 via a minimal Ni3O14 cluster. We find that, at ambient pressure, starting with all three Ni being nominally 2+ valence, one of the two extra holes is localized in the central NiO2 layer forming a Zhang-Rice singlet (ZRS) with dx2-y2 orbital. The other hole mainly occupies the antibonding combination of the two interplane apical O pz orbitals and thereby hybridizes with an out-of-plane three-spin-polaron (3SP) formed by the dz2 orbitals of three NiO2 layers. At high pressure, however, the two extra holes are concentrated on one of two outer layers and the inner layer separately forming the ZRS with dx2-y2 orbitals. We highlight the similarities between the bilayer La3Ni2O7 and trilayer La4Ni3O10 via speculated possible charge and spin configurations as well as the in-plane 3SP on two neighboring clusters suggested by our isolated cluster results.We thereby propose that the hole transfer from apical to in-plane oxygen orbitals of outer layer generates in-plane 3SP-like quasiparticles that act as mobile carriers coupled by interlayer superexchange; while the interplane 3SP-like states may provide the pairing glue. Since the low-pressure phase lacks freely propagating in-plane quasiparticles, this scenario naturally favors SC in the high-pressure phase.