Abstract
Magnetic behavior and disproportionation effect of nickelates are closely related to the nature of their ground state. In the present work, the magnetic structure, lattice dynamics, electronic properties, and disproportionation effect of yttrium nickelate (YNiO3) in its ground state P21/n structure were investigated by first-principles and phonon calculations based on density functional theory (DFT). The strong correlated interactions were treated by the DFT + U approach and the meta-generalized-gradient approximation approach implemented under the strongly constrained appropriately normed functional. The S-type antiferromagnetic insulating ground state of YNiO3 was captured well by both approaches. The disproportionation effect is quantitatively characterized through the Born effective charge, indicating the ligand-hole picture of Ni2+ → Ni2−δ+ Ni2+δ with δ = 0.3. The predicted phonon frequency at the Γ point agrees well with the measured value from infrared experiments, including the longitudinal and transverse optical splitting. The analysis based on stretching force constants indicated that the interaction between Ni and O atoms in the small nonmagnetic NiO6 octahedral clusters is stronger than that in the large magnetic NiO6 octahedral clusters.
Highlights
Perovskite nickelates RNiO3 (R represents yttrium or the rareearth element) are well known for their intriguing structural and physicochemical properties,1–3 such as the metal vs insulator characteristics and various forms of magnetic configurations
The magnetic structure, lattice dynamics, electronic properties, and disproportionation effect of yttrium nickelate (YNiO3) in its ground state P21/n structure were investigated by first-principles and phonon calculations based on density functional theory (DFT)
The DFT + U approach was used to treat the strong on-site Coulomb interaction of the transition metal Ni, and the obtained results were consistently verified using the meta-generalized gradient approximation (GGA) approach implemented under the strongly constrained and approximately normed (SCAN) functional
Summary
Perovskite nickelates RNiO3 (R represents yttrium or the rareearth element) are well known for their intriguing structural and physicochemical properties, such as the metal vs insulator characteristics and various forms of magnetic configurations. Understanding the atomistic underpinnings for magnetic configurations and electronic properties in terms of structural characteristics and stability is, crucial to benefit and extend the applications of RNiO3 nickelates. The bond or charge disproportionation effect is believed to be responsible for the MIT of RNiO3 from the orthorhombic PM phase (with the Pbnm space group) at high temperatures to the monoclinic AFM phase (with the P21/n space group) at low temperatures.. The bond scitation.org/journal/adv disproportionation of two differentiated Ni ions was proposed to be associated with the [Ar]3d8L2 and [Ar]3d8 electronic configurations within Ni sites, where L represents a hole on oxygen p orbitals
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