Orbital fluctuations and spin-orbital-lattice coupling in Bi2Fe4O9

TL;DR

This study reveals strong spin-orbital-lattice coupling in Bi2Fe4O9, demonstrating how KK-type interactions influence phonon behavior, induce ferroelectricity, and affect thermal transport, with implications for magnetoelectric applications.

Contribution

It provides experimental and theoretical evidence of KK-type interactions in Bi2Fe4O9, linking orbital activity to lattice dynamics and ferroelectricity in a frustrated magnetic system.

Findings

Significant change in phonon linewidths not solely due to spin-phonon coupling.

Detection of an unstable polar mode leading to ferroelectric phase below TN.

An anomaly at 57 K correlates with a broad Raman continuum.

Abstract

Magnetic frustrations and degeneracies profoundly affect ground-state magnetic properties emerging from competing exchange interactions. Controlling such frustrations using orbital and phonon engineering via the Kugel-Khomskii-type (KK-type) interactions has recently enabled the orbital enhancement of magnetoelectric (ME) coupling. Using combined spectroscopic techniques and first-principle simulations, here we demonstrate that the magnetically frustrated Cairo lattice, Bi2Fe4O9, exhibits a strong KK-type interaction resulting in a coupled spin-orbital phase below 1.8 times the Neel temperature (TN = 245 K). We observe an order of magnitude change in phonon linewidths that is not explainable considering spin-phonon coupling channels alone. Instead, the observed change is reminiscent of orbitally active materials, which we explicitly confirm by measuring the T-dependence of low-energy orbital excitations. We further find that Bi2Fe4O9 harbors an unstable polar mode, driving the lattice to a symmetry-lowered ferroelectric (FE) phase below TN, in line with the previously reported hysteresis in polarization. Nonetheless, the FE phase leads to extremely small calculated superlattice Bragg peak intensities that are yet to be experimentally confirmed. Moreover, thermal conductivity measurements do not show any measurable effect of KK-type interactions on thermal transport across TN. But, we observe a repeatable anomaly near 57 K appearing only in the heating cycle, which co-occurs with the 400 meV broad continuum observed in Raman measurements. The observed KK-type interaction in Bi2Fe4O9 provides an opportunity for orbital enhancement of ME coupling by phonon control of superexchange interactions.