Stability of equidimensional pseudo–single-domain magnetite over billion-year timescales

Nagy, Lesleis; Williams, Wyn; Muxworthy, Adrian R.; Fabian, Karl; Almeida, Trevor P.; Conbhuí, Pádraig Ó; Щербаков, В. П.

doi:10.1073/pnas.1708344114

Cited by 84 publications

(150 citation statements)

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“…Recent findings about extremely stable vortex states in magnetite (Almeida et al, 2014(Almeida et al, , 2016Nagy et al, 2017) combined with our observations of vortex states in titanomagnetite grains (1-5 μm) suggest that vortex states are probably a common micromagnetic state occurring at the lower end of the PSD size range (Roberts et al, 2017). The variation in domain structures we observed from single domain to four domains might then result from the different cutting planes of octahedral crystals and the resulting 3-D shape of the grains.…”

Section: 1029/2018gc007723supporting

confidence: 71%

“…

Fine particles of titanomagnetites (Fe 3-x Ti x O 4 , x > 0.5) in the pseudo-single-domain (PSD) size (0.5-20 μm) are important carriers of natural remanent magnetization in basalts. These states are characterized by continuous magnetization states emerging as vortices, curls, and flux-closure structures as shown by numerical micromagnetic models (e.g., Nagy et al, 2017;Rave et al, 1998;Williams et al, 2006;Williams & Wright, 1998).According to recent micromagnetic calculations in magnetite, single-vortex states can carry an extremely stable and reliable remanence over billions of years (Nagy et al, 2017). This study reports first observations of magnetic vortex states in intermediate titanomagnetite.

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mentioning

confidence: 67%

“…Yet the mechanism of magnetic recording in PSD grains is not completely understood (e.g., Dunlop & Özdemir, 1997;Fabian & Hubert, 1999;Nagy et al, 2017;Roberts et al, 2017). Fine particles of titanomagnetite in single-domain (SD) or pseudo-single-domain (PSD) states (0.5-20 μm in size) are the dominant carriers of natural remanent magnetization in these rocks.…”

Section: Introductionmentioning

confidence: 99%

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Magnetic Vortex States in Small Octahedral Particles of Intermediate Titanomagnetite

Khakhalova

Moskowitz

Williams

et al. 2018

Geochem Geophys Geosyst

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Fine particles of titanomagnetites (Fe3‐xTixO4, x > 0.5) in the pseudo‐single‐domain (PSD) size (0.5–20 μm) are important carriers of natural remanent magnetization in basalts. Understanding the mechanism of magnetic recording in these grains has important implications for paleomagnetic studies. This study reports first observations of magnetic vortex states in intermediate titanomagnetite. We imaged magnetic structures of 109 synthetic titanomagnetite grains with x = 0.54 (TM54) and 1–4‐μm size using magnetic force microscopy. For six grains, we explored local energy minimum states after alternating field demagnetization and saturation isothermal remanent magnetization. According to the magnetic force microscopy results, 80% of TM54 grains display in‐plane magnetization with one to four domains, vortex‐like or flux‐closure structures, and Néel‐like domain walls. Electron backscatter diffraction data on six grains showed that their surface orientations are cutting planes of octahedral crystals and those with approximately square cross sections are within 15° of a (100) crystallographic plane. Magnetic force microscopy observations of magnetic structures in ~1.5‐μm grains agree well with numerical micromagnetic modeling of a pyramidal shaped grain with a (100) square base and displayed four discrete local energy minimum states: a single vortex as a ground state and three multivortex states with higher energy. Our observations show that vortex states in titanomagnetite grains (1–5 μm) occur at the lower end of the PSD size range in this mineral and corresponding to a size range known to carry stable and reliable remanence in natural titanomagnetites.

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Section: 1029/2018gc007723supporting

confidence: 71%

“…

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mentioning

confidence: 67%

Section: Introductionmentioning

confidence: 99%

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Magnetic Vortex States in Small Octahedral Particles of Intermediate Titanomagnetite

Khakhalova

Moskowitz

Williams

et al. 2018

Geochem Geophys Geosyst

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“…The persistence of weak but stable remanences and the gradual decline in remanence with increasing particle size through the PSD size range is likely explained by the imbalanced nature of magnetic moments in complex magnetic structures within magnetic particles in the vortex state (Einsle et al, ). Available evidence suggests that these structures can record paleomagnetically meaningful information over long geological periods (Almeida et al, , ; Nagy et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…The most important question for paleomagnetic analysis of materials in the magnetic vortex state concerns their magnetic recording capability. Single vortex state particles have been demonstrated to have high field and thermal stability close to the Curie temperature of magnetite (Almeida et al, , ; Einsle et al, ; Muxworthy et al, ; Nagy et al, ), which suggests that they are capable of recording paleomagnetic information over long geological periods. This confirms the paleomagnetic recording fidelity of PSD particles that has been postulated for over 55 years.…”

Section: Evidence For Magnetic Vortices From Electron Holographymentioning

confidence: 99%

Resolving the Origin of Pseudo‐Single Domain Magnetic Behavior

et al. 2017

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The term “pseudo‐single domain” (PSD) has been used to describe the transitional state in rock magnetism that spans the particle size range between the single domain (SD) and multidomain (MD) states. The particle size range for the stable SD state in the most commonly occurring terrestrial magnetic mineral, magnetite, is so narrow (~20–75 nm) that it is widely considered that much of the paleomagnetic record of interest is carried by PSD rather than stable SD particles. The PSD concept has, thus, become the dominant explanation for the magnetization associated with a major fraction of particles that record paleomagnetic signals throughout geological time. In this paper, we argue that in contrast to the SD and MD states, the term PSD does not describe the relevant physical processes, which have been documented extensively using three‐dimensional micromagnetic modeling and by parallel research in material science and solid‐state physics. We also argue that features attributed to PSD behavior can be explained by nucleation of a single magnetic vortex immediately above the maximum stable SD transition size. With increasing particle size, multiple vortices, antivortices, and domain walls can nucleate, which produce variable cancellation of magnetic moments and a gradual transition into the MD state. Thus, while the term PSD describes a well‐known transitional state, it fails to describe adequately the physics of the relevant processes. We recommend that use of this term should be discontinued in favor of “vortex state,” which spans a range of behaviors associated with magnetic vortices.

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MERRILL: Micromagnetic Earth Related Robust Interpreted Language Laboratory

Conbhuí

Williams

Fabian

et al. 2018

Geochem Geophys Geosyst

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Complex magnetic domain structures and the energy barriers between them are responsible for pseudo‐single‐domain phenomena in rock magnetism and contribute significantly to the magnetic remanence of paleomagnetic samples. This article introduces MERRILL, an open source software package for three‐dimensional micromagnetics optimized and designed for the calculation of such complex structures. MERRILL has a simple scripting user interface that requires little computational knowledge to use but provides research strength algorithms to model complex, inhomogeneous domain structures in magnetic materials. It uses a finite element/boundary element numerical method, optimally suited for calculating magnetization structures of local energy minima (LEM) in irregular grain geometries that are of interest to the rock and paleomagnetic community. MERRILL is able to simulate the magnetic characteristics of LEM states in both single grains, and small assemblies of interacting grains, including saddle‐point paths between nearby LEMs. Here the numerical model is briefly described, and an overview of the scripting language and available commands is provided. The open source nature of the code encourages future development of the model by the scientific community.

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Stability of equidimensional pseudo–single-domain magnetite over billion-year timescales

Cited by 84 publications

References 33 publications

Magnetic Vortex States in Small Octahedral Particles of Intermediate Titanomagnetite

Magnetic Vortex States in Small Octahedral Particles of Intermediate Titanomagnetite

Resolving the Origin of Pseudo‐Single Domain Magnetic Behavior

MERRILL: Micromagnetic Earth Related Robust Interpreted Language Laboratory

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