Spin-state ordering and magnetic structures in the cobaltites YBaCo2O5+delta (delta=0.50 and 0.44)

abstract

The antiferromagnetic-ferromagnetic phase transition in YBaCo2O5.50 and YBaCo2O5.44 cobaltites with different types of oxygen-ion ordering in the [YO0.5/0.44] layers has been studied by neutron powder diffraction in combination with group-theoretical analysis. As a result, the crystal and magnetic structures above and below the phase transformation temperature T-i were determined and successfully refined. In both cases, the proposed models involve a spin-state ordering between diamagnetic (t(2g)(6)e(g)(0), S=0) and paramagnetic (t(2g)(4)e(g)(2), S=2) Co3+ ions with octahedral coordination. Electronic ordering results in a nonzero spontaneous magnetic moment in the high-temperature magnetic phases with isotropic negative exchange interactions. In the case of YBaCo2O5.5, the phase transformation does not change the Pmma (2a(p) x 2a(p) x 2a(p)) symmetry of the crystal structure. The wave vectors of magnetic structures above and below T-i are k=0 and k=c(*)/2, respectively. In the case of YBaCo2O5.44 a crossover P4/nmm (3 root 2a(p) x 3 root 2a(p) x 2ap) -> I4/mmm (3 root 2a(p) x 3 root 2a(p) x 4a(p)) was involved to solve the low-temperature magnetic structure. The wave vectors in both high-temperature and low-temperature magnetic phases are k=0. Mechanisms of the phase transformation in both compositions are discussed in the light of obtained magnetic structures. The proposed spin configurations were compared with other models reported in literature.

keywords

NEUTRON POWDER DIFFRACTION; TRANSPORT-PROPERTIES; PHASE-TRANSITIONS; PEROVSKITE; LACOO3; NDBACO2O5+DELTA; TBBACO2O5.5; INTERPLAY; CRYSTAL; TB

subject category

Physics

authors

Khalyavin, DD; Argyriou, DN; Amann, U; Yaremchenko, AA; Kharton, VV

our authors

Share this project:

Related Publications

We use cookies for marketing activities and to offer you a better experience. By clicking “Accept Cookies” you agree with our cookie policy. Read about how we use cookies by clicking "Privacy and Cookie Policy".