Abstract
To understand the influence of doping Sr atoms on the structural, magnetic, and electronic properties of the infinite-layer NdSrNiO(2), we carried out the screened hybrid density functional study on the Nd(9-n)Sr(n)Ni(9)O(18) (n = 0-2) unit cells. Geometries, substitution energies, magnetic moments, spin densities, atom- and lm-projected partial density of states (PDOS), spin-polarized band structures, and the average Bader charges were studied. It showed that the total magnetic moments of the Nd(9)Ni(9)O(18) and Nd(8)SrNi(9)O(18) unit cells are 37.4 and 24.9 emu g(-1), respectively. They are decreased to 12.6 and 4.2 emu g(-1) for the Nd(7)Sr(2)Ni(9)O(18)-Dia and Nd(7)Sr(2)Ni(9)O(18)-Par unit cells. The spin density distributions demonstrated that magnetic disordering of the Ni atoms results in the magnetism decrease. The spin-polarized band structures indicated that the symmetry of the spin-up and spin-down energy bands around the Fermi levels also influence the total magnetic moments. Atom- and lm-projected PDOS as well as the band structures revealed that Ni(dx2-y2) is the main orbital intersecting the Fermi level. As a whole, electrons of Sr atoms tend to locate locally and hybridize weakly with the O atoms. They primarily help to build the infinite-layer structures, and influence the electronic structure near the Fermi level indirectly.