The Verwey structure of a natural magnetite

A remarkably complex electronic order of Fe 2+ /Fe 3+ charges, Fe 2+ orbital states, and weakly metal-metal bonded Fe 3 units known as trimerons, was recently discovered in stoichiometric magnetite (Fe 3 O 4 ) below the 125 K Verwey transition. Here, the low temperature crystal structure of a natura...

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Bibliographic Details
Published in:Chemical communications (Cambridge, England) England), 2016-04, Vol.52 (27), p.4864-4867
Main Authors: Perversi, G, Cumby, J, Pachoud, E, Wright, J. P, Attfield, J. P
Format: Article
Language:English
Subjects:
Aluminum
Diffraction
Electronics
Extraterrestrial environments
Ferrosoferric Oxide - chemistry
Magnesium
Magnetite
Molecular Conformation
Orbitals
Reduction
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Summary:A remarkably complex electronic order of Fe 2+ /Fe 3+ charges, Fe 2+ orbital states, and weakly metal-metal bonded Fe 3 units known as trimerons, was recently discovered in stoichiometric magnetite (Fe 3 O 4 ) below the 125 K Verwey transition. Here, the low temperature crystal structure of a natural magnetite from a mineral sample has been determined using the same microcrystal synchrotron X-ray diffraction method. Structure refinement demonstrates that the natural sample has the same complex electronic order as pure synthetic magnetite, with only minor reductions of orbital and trimeron distortions. Chemical analysis shows that the natural sample contains dopants such as Al, Si, Mg and Mn at comparable concentrations to extraterrestrial magnetites, for example, as reported in the Tagish Lake meteorite. Much extraterrestrial magnetite exists at temperatures below the Verwey transition and hence our study demonstrates that the low temperature phase of magnetite represents the most complex long-range electronic order known to occur naturally. Complex charge and orbital molecule order observed in natural magnetite comparable to meteoritic samples is the most complex electronic order known to occur naturally.
ISSN:1359-7345
1364-548X
DOI:10.1039/c5cc10495e