Possible thermal and chemical stabilization of body-centred-cubic iron in the Earth's core

Possible thermal and chemical stabilization of body-centred-cubic iron in the Earth's core

The nature of the stable phase of iron in the Earth's solid inner core is still highly controversial. Laboratory experiments suggest the possibility of an uncharacterized phase transformation in iron at core conditions and seismological observations have indicated the possible presence of compl...

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Bibliographic Details
Published in:Nature (London) Vol. 424; no. 6948; pp. 536 - 539
Main Authors: Vo adlo, Lidunka, Alfè, Dario, Gillan, M. J, Wood, I. G, Brodholt, J. P, Price, G. David
Format: Journal Article
Language:English
Published: London Nature Publishing 31-07-2003
Nature Publishing Group
Subjects:
Earth
Earth core
Earth sciences
Earth, ocean, space
Exact sciences and technology
High pressure
High temperature
Internal geophysics
Iron
Physics
Solid-earth geophysics, tectonophysics, gravimetry
experimental studies
stress
models
alloys
stabilization
stratification
impurities
simulation
seismology
thermodynamics
tensor
vibration
high pressure
high temperature
entropy
silicon
free energy
phase transformation
crystal structure
iron
sulfur
inner core
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Summary:The nature of the stable phase of iron in the Earth's solid inner core is still highly controversial. Laboratory experiments suggest the possibility of an uncharacterized phase transformation in iron at core conditions and seismological observations have indicated the possible presence of complex, inner-core layering. Theoretical studies currently suggest that the hexagonal close packed (h.c.p.) phase of iron is stable at core pressures and that the body centred cubic (b.c.c.) phase of iron becomes elastically unstable at high pressure. In other h.c.p. metals, however, a high-pressure b.c.c. form has been found to become stabilized at high temperature. We report here a quantum mechanical study of b.c.c.-iron able to model its behaviour at core temperatures as well as pressures, using ab initio molecular dynamics free-energy calculations. We find that b.c.c.-iron indeed becomes entropically stabilized at core temperatures, but in its pure state h.c.p.-iron still remains thermodynamically more favourable. The inner core, however, is not pure iron, and our calculations indicate that the b.c.c. phase will be stabilized with respect to the h.c.p. phase by sulphur or silicon impurities in the core. Consequently, a b.c.c.-structured alloy may be a strong candidate for explaining the observed seismic complexity of the inner core.
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ISSN:0028-0836
1476-4687
DOI:10.1038/nature01829