Abstract
AbstractThree‐dimensional geometries of silicate‐hosted magnetic inclusions from the Harcus intrusion, South Australia have been determined using focused‐ion‐beam nanotomography (FIB‐nt). By developing an effective workflow, the geometries were reconstructed for magnetic particles in a plagioclase (162) and a pyroxene (282), respectively. For each inclusion, micromagnetic modeling using Micromagnetic Earth Related Rapid Interpreted Language Laboratory provided averaged hysteresis loops and backfield remanence curves of 20 equidistributed field directions together with average Ms, Mrs, Hc, and Hcr. The micromagnetic structures within each silicate are single‐domain (SD), single‐vortex (SV), multivortex (MV) and multidomain states. They have been analyzed using domain‐state diagnostic plots, such as the Day plot and the Néel plot. SD particles can be subdivided into groups with dominant uniaxial anisotropy (Mrs/Ms ∼0.5 and 10 < Hc < 100 mT) and mixed uniaxial/multiaxial anisotropy (Mrs/Ms ∼0.7 and 10 < Hc < 30 mT). Most SV particles lie on a trend with 0 < Mrs/Ms < 0.1 and 0 < Hc < 10 mT, while others display a broad range of intermediate Mrs/Ms and Hc values. SV and MV states do not plot on systematic grain‐size trends. Instead, the multicomponent mixture of domain states within each silicate spans the entire range of natural variability seen in bulk samples. This questions the interpretation of bulk average hysteresis parameters in terms of grain size alone. FIB‐nt combined with large‐scale micromagnetic simulations provides a more complete characterization of silicate‐hosted carriers of stable magnetic remanence. This approach will improve the understanding of single‐crystal paleomagnetism and enable primary paleomagnetic data to be extracted from ancient rocks.
Highlights
A fundamental task in rock magnetism is to identify the magnetic domain states adopted by natural remanence carriers because these control the remanence acquisition process, the stability of the remanent magnetization over geological time, and subsequently the reliability of the stored paleomagnetic information
The complexities of particle size, shape, spacing, chemical composition, stoichiometry, and stress will generate unique mineralogical settings, and it is a fair question raised by Lascu et al (2015) whether domain-state diagnosis might be an unachievable ideal? Here, we show that focused-ion-beam nanotomography (FIB-nt)-finite element micromagnetic (FEM) is able to resolve domain-state ambiguities associated with the size, shape, and spacing of particles
We extracted a total of 162 particles of magnetite and were able to run hysteresis loops for 140 of these
Summary
A fundamental task in rock magnetism is to identify the magnetic domain states adopted by natural remanence carriers because these control the remanence acquisition process, the stability of the remanent magnetization over geological time, and subsequently the reliability of the stored paleomagnetic information. Rock magnetism broadly classifies these particles into superparamagnetic (SP), stable single-domain (SD), pseudo-single-domain (PSD), and multidomain (MD) states, with the boundaries between states originally based on experimental results Magnetite particles directly above the upper SD limit assume an intermediate state in experimental and theoretical studies. Because they appear to be related to a stable and SD-like experimental behavior, for which Stacey (1961) coined the notion of PSD remanence, they are commonly referred to as PSD particles.
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