Efficiency of thermoremanent magnetization acquisition in vortex-state particle assemblies: Dataset and Codes
Creators
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1.
University of Edinburgh
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2.
Imperial College London
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3.
Universidade de São Paulo
- 4. University of Liverpool
Description
When magma cools, crystallized magnetic minerals can record the ambient magnetic field. If these mineral grains are sufficiently small, they may retain that magnetic record for billions of years. This phenomenon enables paleomagnetists to study the direction and intensity of ancient magnetic fields on Earth and other planets. A key task is determining the number of magnetic particles required to reliably record such a field, as well as understanding the influence of grain size and shape on this process. Here, we present a dataset from the study titled "Efficiency of Thermoremanent Magnetization Acquisition in Vortex-State Particle Assemblies," which integrates micromagnetic modeling and probabilistic magnetic state partitioning to address these questions. The dataset includes codes for the micromagnetic simulations and data from all the simulations conducted.
Files
Supplementary_Data.zip
Files
(437.4 MB)
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md5:e3888b2f9344c84541e6981e39b66fea
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Additional details
Funding
- Natural Environment Research Council
- Thermochemical remanent magnetisations: How do they affect ancient magnetic field intensities from the Earth and Solar System? NE/V001388/1
- Natural Environment Research Council
- Particles to Planets: Unravelling the history of our magnetic field NE/W006707/1
- Natural Environment Research Council
- NSFGEO-NERC: Transforming understanding of paleomagnetic recording: Insights from experimental observations and numerical predictions NE/S011978/1
- Natural Environment Research Council
- MicroPI: A micromagnetic approach to absolute palaeointensity determinations NE/Z000068/1
- Fundação de Amparo à Pesquisa do Estado de São Paulo
- Acquisition and chemical remagnetization in carbonates: an evaluation by micromagnetic modeling, laboratory simulations and case studies 21/00861-2
- Fundação de Amparo à Pesquisa do Estado de São Paulo
- Exploring micromagnetic modelling of highly-detailed three-dimensional finite element meshes: a new pathway to study the properties of remanence carriers in remagnetized carbonates 22/14100-6
Dates
- Created
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2024-11-07