Magnetic field induced structural changes in magnetite observed by resonant x-ray diffraction and Mössbauer spectroscopy

Kołodziej, Tomasz; Bialo, I.; Tabiś, Wojciech; Zubko, Maciej; Żukrowski, J.; Łątka, Kazimierz; Lorenzo, J. E.; Mazzoli, Claudio; Ka̧kol, Z.; Kozłowski, A.; Tarnawski, Z.; Wilke, E.; Bábík, Pavel; Chlan, V.; Řezníček, R.; Štěpánková, H.; Novák, P.; Joly, Yves; Niewolski, J.; Honig, J. M.

doi:10.1103/physrevb.102.075126

“…The obtained results can be compared with other studies which probe the local charge distribution on Fe B ions. The NMR and Mössbauer measurements combined with DFT calculations revealed that all B-sites can be divided into three groups with the ratio 8:5:3 [18,19,77,78]. The first group consists of 8 Fe 3+ ions, the second group includes 5 Fe 2+ ions in which electrons occupy the d xz or d yz orbitals, and the third group comprises 3 Fe 2+ ions with occupied d xy orbitals.…”

Section: Final Discussion and Summarymentioning

confidence: 99%

Trimeron-phonon coupling in magnetite

Piekarz

¹

,

Legut

²

,

Baldini

³

et al. 2021

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Using density functional theory, we study the lattice dynamical properties of magnetite (Fe3O4) in the high-temperature cubic and low-temperature monoclinic phases. The calculated phonon dispersion curves and phonon density of states are compared with the available experimental data obtained by inelastic neutron, inelastic x-ray, and nuclear inelastic scattering. We find a very good agreement between the theoretical and experimental results for the monoclinic Cc structure revealing the strong coupling between charge-orbital (trimeron) order and specific phonon modes. For the cubic phase, clear discrepancies arise which, remarkably, can be understood assuming that the strong trimeron-phonon coupling can be extended above the Verwey transition, with lattice dynamics influenced by the short-range trimeron order instead of the average cubic structure. Our results establish the validity of trimerons (and trimeron-phonon coupling) in explaining the physics of magnetite much beyond their original formulation.

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“…24 , 25 Further Mössbauer and resonant X-ray experiments have suggested that trimeron direction changes around a fixed central Fe 2+ ion when the easy magnetization axis of the Cc phase is switching by an applied magnetic field. 27 Recent phonon calculations for the Cc structure have shown good agreement with inelastic neutron, X-ray, and nuclear scattering data, revealing strong trimeron–phonon coupling, especially for trimerons oriented parallel to the axes of the monoclinic Cc cell. 28 …”

Section: Resultsmentioning

confidence: 78%

“…The four signals are in an 8:8:5:3 ratio to account respectively for 8 A-site Fe 3+ ions, 8 B-site Fe 3+ ions, 5 B-site Fe 2+ ions where the extra electron occupies d xz or d yz orbitals, and 3 B-site Fe 2+ ions with the extra electron in the d xy orbital. The latter group is distinct as the d xy orbitals lie perpendicular to the magnetization in the Cc structure giving rise to lower effective magnetic fields and larger electric field gradients, and they also have distinctive NMR frequencies. , Further Mössbauer and resonant X-ray experiments have suggested that trimeron direction changes around a fixed central Fe 2+ ion when the easy magnetization axis of the Cc phase is switching by an applied magnetic field . Recent phonon calculations for the Cc structure have shown good agreement with inelastic neutron, X-ray, and nuclear scattering data, revealing strong trimeron–phonon coupling, especially for trimerons oriented parallel to the axes of the monoclinic Cc cell …”

Section: Resultsmentioning

confidence: 95%

“…Much of this has been enabled by technique developments. In particular, state-of-the art X-ray synchrotron beamlines have been used for microcrystal determinations of the Cc ground state crystal structure, 3 , 16 , 53 , 54 resonant and multiwave diffraction studies, 19 , 27 nuclear inelastic scattering, 50 ambient and high pressure powder diffraction studies, 32 , 45 diffuse and total scattering (PDF) experiments, 37 , 45 , 46 X-ray absorption spectroscopy and MCD, 36 and resonant and nonresonant IXS, 41 − 44 with the majority of these experiments performed at the ESRF. Coherent light sources have also been important for pump–probe studies of lattice dynamics.…”

Section: Discussionmentioning

confidence: 99%

“…Much of this has been enabled by technique developments. In particular, state-of-the art X-ray synchrotron beamlines have been used for microcrystal determinations of the Cc ground state crystal structure, ,,, resonant and multiwave diffraction studies, , nuclear inelastic scattering, ambient and high pressure powder diffraction studies, , diffuse and total scattering (PDF) experiments, ,, X-ray absorption spectroscopy and MCD, and resonant and nonresonant IXS, − with the majority of these experiments performed at the ESRF. Coherent light sources have also been important for pump–probe studies of lattice dynamics. , Improved DFT codes have supported many of these investigations, also enabling accurate NMR and Mössbauer spectra to be simulated. − , Developments in nanoparticle chemistry have enabled influences of particle size and oxygen content on the Verwey transiton to be determined in exquisite detail. , High pressure discoveries of new mixed-valent binary iron oxides have broadened insights into magnetite. ,− …”

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

Magnetism and the Trimeron Bond

Attfield

¹

2022

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A review of progress in understanding the Verwey transition in magnetite (Fe 3 O 4 ) over the past decade is presented. This electronic and structural transition at T V ≈ 125 K was reported in 1939 and has since been a contentious issue in magnetism. Long range Fe 2+ /Fe 3+ charge ordering has been confirmed below the transition from crystal structure refinement, and Fe 2+ orbital ordering and formation of trimerons through weak bonding of Fe 2+ states to two Fe neighbors has been discovered. This model has accounted for many spectroscopic observations such as the 57 Fe NMR frequencies. The trimeron lifetime has been measured, and trimeron soft modes have been observed. The origin of the first to second order crossover of Verwey transitions in doped magnetites has been revealed by a nanoparticle study. Electronic and structural fluctuations are found to persist to temperatures far above T V and local structural distortions track the bulk magnetization, disappearing at the 850 K Curie transition. New binary mixed-valent iron oxides discovered at high pressure are found to have electronic transitions and orbital molecule ground states similar to those of magnetite.

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