Hole distribution and self-doping enhanced electronic correlation in hole-doped infinite-layer nickelates

Abstract

The minimal model for infinite-layer nickelates remains under debate, particularly regarding the hybridization between itinerant interstitial-s and the correlated Ni-3dx2-y2 orbitals, as well as the interaction between dx2-y2 and other 3d orbitals. Additionally, how the doped holes in La1-xSrxNiO2 are distributed among different orbitals remain unresolved. Motivated by recent angle resolved photoemission spectroscopy (ARPES) experiments, we theoretically study the electronic structure of infinite-layer La1-xSrxNiO2 at various doping levels. We find that, unlike the expectation from a rigid band shift, holes are equally distributed to Ni-3dx2-y2 and interstitial-s orbitals. The role of interstitial-s orbital is further confirmed from the renormalization of Ni-3dx2-y2 band, for which the coupling between interstitial-s and Ni-3dx2-y2 exerts a non-negligible impact on the orbital-selective renormalization observed in ARPES. We also discuss the implication of our results to the single-band model, where the interstitial-s orbital in the normal state of La1-xSrxNiO2 acts as charge donator enhancing the correlation of Ni-3dx2-y2 by increasing its concentration close to half-filling.