Efficiency of Thermoremanent Magnetization Acquisition in Vortex‐State Particle Assemblies

Efficiency of Thermoremanent Magnetization Acquisition in Vortex‐State Particle Assemblies

Abstract Magmatic rocks record ambient magnetic fields during cooling, preserving them for billions of years through thermoremanent magnetization (TRM). TRM accuracy depends on particle size, shape, magnetic properties, and the number of particles available to record the field. While traditionally i...

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Bibliographic Details
Main Authors: U. D. Bellon, W. Williams, A. R. Muxworthy, G. F. Souza‐Junior, L. Nagy, L. Uieda, R. I. F. Trindade
Format: Article
Language:English
Published: Wiley 2025-04-01
Series:Geophysical Research Letters
Subjects:
magnetic mineralogy
thermoremanence
micromagnetic modeling
paleomagnetism
natural remanent magnetization
vortex‐state
Online Access:https://doi.org/10.1029/2025GL114771
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Summary:Abstract Magmatic rocks record ambient magnetic fields during cooling, preserving them for billions of years through thermoremanent magnetization (TRM). TRM accuracy depends on particle size, shape, magnetic properties, and the number of particles available to record the field. While traditionally interpreted via Neél's single‐domain theory, most particles exist in a vortex state, where complex magnetic structures require numerical modeling. We show that in fields >10μT, a few thousand nanoscopic vortex‐state particles can record TRM with less than 1° error, regardless of shape. For weaker fields, morphology plays a crucial role, with spherical and oblate particles performing best. These findings challenge assumptions about particle requirements for faithful TRM recording and highlight the influence of grain shape in paleomagnetic studies. Our results justify using smaller geological samples and magnetic microscopy to reconstruct ancient magnetic fields with precision.
ISSN:0094-8276
1944-8007

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