Mechanochemical Enhancement of Siderite-To-Magnetite Conversion in Faults

Tingting Du; Tao Yang; Lu Yao; Qi Zhang; Ting Li; Tsafrir Levi; Ram Weinberger; Shmuel Marco

doi:10.1029/2025GL118677

Mechanochemical Enhancement of Siderite-To-Magnetite Conversion in Faults

Tingting Du
, Tao Yang^*
, Lu Yao^*
, Qi Zhang
, Ting Li
, Tsafrir Levi
, Ram Weinberger
, Shmuel Marco

^*Corresponding author for this work

Department of Geophysics

China University of Geosciences, Beijing
China Earthquake Administration
China National Nuclear Corporation
Geological Survey of Israel
Ben-Gurion University of the Negev

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Magnetic phases in fault rocks offer potential “geothermometers” for estimating frictional heating during fault slip. However, the thermochemical kinetics of magnetic minerals subjected to shear deformation in hydrothermal fluids-conditions typical of natural faults - remains poorly understood, hindering accurate temperature estimates. We examined the influence of mechanical shearing on magnetic and thermochemical changes of siderite through low-velocity friction and compaction experiments, complemented by rock magnetic, thermogravimetric, microscopic and X-ray diffraction (XRD) analyses. Results show that mechanical shearing can significantly lower the thermal stability of siderite, likely through crystallite refinement and/or lattice distortion. This facilitates thermochemical reactions of siderite and lowers the onset temperature to ∼269°C for its conversion to magnetite in fault zones. Therefore, such an effect should be considered not only when estimating frictional heating via magnetic assemblages, but also in thermochemical studies of carbonates beyond siderite, such as investigations of the fate of carbonates in subduction zones.

Original language	English
Article number	e2025GL118677
Journal	Geophysical Research Letters
Volume	53
Issue number	5
DOIs	https://doi.org/10.1029/2025GL118677
State	Published - 16 Mar 2026

Funding

Funders	Funder number
National Natural Science Foundation of China
Bjarne Almqvist
ISF	3616/21, 42161144009
Institute of Geology, China Earthquake Administration	1164/23, IGCEA2107

Keywords

fault zones
geothermometer
mechanical shearing
rock magnetism
siderite
thermal stability

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10.1029/2025GL118677

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title = "Mechanochemical Enhancement of Siderite-To-Magnetite Conversion in Faults",

abstract = "Magnetic phases in fault rocks offer potential “geothermometers” for estimating frictional heating during fault slip. However, the thermochemical kinetics of magnetic minerals subjected to shear deformation in hydrothermal fluids-conditions typical of natural faults - remains poorly understood, hindering accurate temperature estimates. We examined the influence of mechanical shearing on magnetic and thermochemical changes of siderite through low-velocity friction and compaction experiments, complemented by rock magnetic, thermogravimetric, microscopic and X-ray diffraction (XRD) analyses. Results show that mechanical shearing can significantly lower the thermal stability of siderite, likely through crystallite refinement and/or lattice distortion. This facilitates thermochemical reactions of siderite and lowers the onset temperature to ∼269°C for its conversion to magnetite in fault zones. Therefore, such an effect should be considered not only when estimating frictional heating via magnetic assemblages, but also in thermochemical studies of carbonates beyond siderite, such as investigations of the fate of carbonates in subduction zones.",

keywords = "fault zones, geothermometer, mechanical shearing, rock magnetism, siderite, thermal stability",

author = "Tingting Du and Tao Yang and Lu Yao and Qi Zhang and Ting Li and Tsafrir Levi and Ram Weinberger and Shmuel Marco",

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year = "2026",

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day = "16",

doi = "10.1029/2025GL118677",

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T1 - Mechanochemical Enhancement of Siderite-To-Magnetite Conversion in Faults

AU - Du, Tingting

AU - Yang, Tao

AU - Yao, Lu

AU - Zhang, Qi

AU - Li, Ting

AU - Levi, Tsafrir

AU - Weinberger, Ram

AU - Marco, Shmuel

PY - 2026/3/16

Y1 - 2026/3/16

N2 - Magnetic phases in fault rocks offer potential “geothermometers” for estimating frictional heating during fault slip. However, the thermochemical kinetics of magnetic minerals subjected to shear deformation in hydrothermal fluids-conditions typical of natural faults - remains poorly understood, hindering accurate temperature estimates. We examined the influence of mechanical shearing on magnetic and thermochemical changes of siderite through low-velocity friction and compaction experiments, complemented by rock magnetic, thermogravimetric, microscopic and X-ray diffraction (XRD) analyses. Results show that mechanical shearing can significantly lower the thermal stability of siderite, likely through crystallite refinement and/or lattice distortion. This facilitates thermochemical reactions of siderite and lowers the onset temperature to ∼269°C for its conversion to magnetite in fault zones. Therefore, such an effect should be considered not only when estimating frictional heating via magnetic assemblages, but also in thermochemical studies of carbonates beyond siderite, such as investigations of the fate of carbonates in subduction zones.

AB - Magnetic phases in fault rocks offer potential “geothermometers” for estimating frictional heating during fault slip. However, the thermochemical kinetics of magnetic minerals subjected to shear deformation in hydrothermal fluids-conditions typical of natural faults - remains poorly understood, hindering accurate temperature estimates. We examined the influence of mechanical shearing on magnetic and thermochemical changes of siderite through low-velocity friction and compaction experiments, complemented by rock magnetic, thermogravimetric, microscopic and X-ray diffraction (XRD) analyses. Results show that mechanical shearing can significantly lower the thermal stability of siderite, likely through crystallite refinement and/or lattice distortion. This facilitates thermochemical reactions of siderite and lowers the onset temperature to ∼269°C for its conversion to magnetite in fault zones. Therefore, such an effect should be considered not only when estimating frictional heating via magnetic assemblages, but also in thermochemical studies of carbonates beyond siderite, such as investigations of the fate of carbonates in subduction zones.

KW - fault zones

KW - geothermometer

KW - mechanical shearing

KW - rock magnetism

KW - siderite

KW - thermal stability

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ER -

Mechanochemical Enhancement of Siderite-To-Magnetite Conversion in Faults

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