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Spin-phonon interactions and magnetoelectric coupling in Co₄B₂O₉ (B = Nb, Ta)

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arxiv 2304.04865 v1 pith:76EVMH4M submitted 2023-04-10 cond-mat.mtrl-sci cond-mat.other

Spin-phonon interactions and magnetoelectric coupling in Co₄B₂O₉ (B = Nb, Ta)

classification cond-mat.mtrl-sci cond-mat.other
keywords couplingspin-phononinteractionsoxidestemperatureconstantsdifferentinterlayer
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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In order to explore the consequences of spin-orbit coupling on spin-phonon interactions in a set of chemically-similar mixed metal oxides, we measured the infrared vibrational properties of Co$_4B_2$O$_9$ ($B$ = Nb, Ta) as a function of temperature and compared our findings with lattice dynamics calculations and several different models of spin-phonon coupling. Frequency vs. temperature trends for the Co$^{2+}$ shearing mode near 150 cm$^{-1}$ reveal significant shifts across the magnetic ordering temperature that are especially large in relative terms. Bringing these results together and accounting for noncollinearity, we obtain spin-phonon coupling constants of -3.4 and -4.3 cm$^{-1}$ for Co$_4$Nb$_2$O$_9$ and the Ta analog, respectively. Analysis reveals that these coupling constants derive from interlayer (rather than intralayer) exchange interactions and that the interlayer interactions contain competing antiferromagnetic and ferromagnetic contributions. At the same time, beyond-Heisenberg terms are minimized due to fortuitous symmetry considerations, different than most other 4$d$- and 5$d$-containing oxides. Comparison with other contemporary oxides shows that spin-phonon coupling in this family of materials is among the strongest ever reported, suggesting an origin for magnetoelectric coupling.

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