Loading…

Spin Transition of Iron in δ‐(Al,Fe)OOH Induces Thermal Anomalies in Earth's Lower Mantle

Seismic anomalies observed in Earth's deep mantle are conventionally considered to be associated with thermal and compositional anomalies, and possibly partial melt of major lower‐mantle phases. However, through deep water cycle, impacts of hydrous minerals on geophysical observables and on the...

Full description

Saved in:
Bibliographic Details
Published in:Geophysical research letters 2020-02, Vol.47 (4), p.n/a
Main Authors: Hsieh, Wen‐Pin, Ishii, Takayuki, Chao, Keng‐Hsien, Tsuchiya, Jun, Deschamps, Frédéric, Ohtani, Eiji
Format: Article
Language:English
Subjects:
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Seismic anomalies observed in Earth's deep mantle are conventionally considered to be associated with thermal and compositional anomalies, and possibly partial melt of major lower‐mantle phases. However, through deep water cycle, impacts of hydrous minerals on geophysical observables and on the deep mantle thermal state and geodynamics remain poorly understood. Here we precisely measured thermal conductivity of δ‐(Al,Fe)OOH, an important water‐carrying mineral in Earth's deep interior, to lowermost mantle pressures at room temperature. The thermal conductivity varies drastically by twofold to threefold across the spin transition of iron, resulting in an exceptionally low thermal conductivity at the lowermost mantle conditions. As δ‐(Al,Fe)OOH is transported to the lowermost mantle, its exceptionally low thermal conductivity may serve as a local thermal insulator, promoting high‐temperature anomalies and the formation of partial melt and thermal plumes at the base of the mantle, strongly influencing thermo‐chemical profiles in the region and fate of Earth's deep water cycle. Plain Language Summary Hydrous minerals subducted to Earth's deep interior may critically affect the thermo‐chemical and seismic signatures observed at the bottom of the mantle. We measured thermal conductivity of δ‐(Al,Fe)OOH, an important water carrier in deep Earth, to the lowermost mantle pressures. Its thermal conductivity varies drastically across the spin transition of iron and approaches an exceptionally low value of ~5 W·m−1·K−1 at the lowermost mantle conditions, much smaller than the pyrolitic mantle. Such anomalous evolution of thermal conductivity would induce anomalies in heat flux and temperature profile in the lower mantle. It could create a local thermal insulating effect that heats up slab's crust at the lowermost mantle, facilitating dehydration melting of surrounding mantle and affecting thermo‐chemical features in the region. Key Points We combined ultrafast optics with diamond‐anvil cell to study high‐pressure thermal conductivity of δ‐(Al,Fe)OOH Within the spin transition zone the thermal conductivity of δ‐(Al,Fe)OOH varies drastically with pressure Its exceptionally low thermal conductivity at the lowermost mantle may induce thermal anomalies, altering local thermo‐chemical structures
ISSN:0094-8276
1944-8007
DOI:10.1029/2020GL087036