Matuyama–Brunhes geomagnetic reversal record and associated key tephra layers in Boso Peninsula: extraction of primary magnetization of geomagnetic fields from mixed magnetic minerals of depositional, diagenesis, and weathering processes

The Matuyama-Brunhes reversal (MBR) is the most recent magnetic field reversal, and characterizing it globally is important to understand the geodynamo processes in Earth's core. Also, it is an essential chronozone boundary of the Quaternary magnetic polarity reversal timescale (Cande & Kent, 1995;Channell et al., 2020;Cohen & Gibbard, 2019;Ogg, 2020;Singer, 2014), therefore identifying its age is crucial for enhancing marine stratigraphy, correlation of rock sequences, and refining our understanding of global climate changes (Bassinot et al., 1994), among other applications. Marine and lacustrine sediments, lava flows, and ice cores are commonly used for MBR investigation. Despite the relative abundance of these data, different ages have been proposed for the MBR over the last decades: 730 ka (

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Characteristics of the Matuyama‐Brunhes Magnetic Field Reversal Based on a Global Data Compilation

Mahgoub

Korte

Panovska

2023

JGR Solid Earth

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Global Geomagnetic Field Evolution From 900 to 700 ka Including the Matuyama‐Brunhes Reversal

2023

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Polarity reversals and excursions are the most significant geomagnetic field changes generated in the liquid outer core of the Earth, therefore studying them helps understand geodynamo processes. This study examines the Matuyama‐Brunhes (MB) reversal using a new reconstruction of the global geomagnetic field based on paleomagnetic data, termed Global Geomagnetic Field Model for the MB reversal (GGFMB). GGFMB covers 900–700 ka, including late Matuyama and early Brunhes. This allows us to also investigate the Kamikatsura excursion (ca. 888 ka). The model is based on 38 high‐quality paleomagnetic sediment records with age control mostly independent of the magnetic signal. GGFMB suggests that the MB reversal began about ∼799 ka, when non‐dipole field components increased and the axial dipole component decreased. The transitional fields first appeared on Earth's surface in the high‐latitude southern hemisphere and equatorial regions. The minimum dipole strength was reached around 780 ka and the axial dipole changed sign. After ∼10 Kyr, the field stabilized in the normal polarity of the early Brunhes. The MB reversal lasted ∼29 Kyr (from 799 to 770 ka) and had slower rate of dipole decay than recovery as well as lower dipole moment for several millennia before than after the reversal. According to GGFMB, the dipole moment during the Kamikatsura excursion was approximately half that of the current field and it was a regional excursion observed only over eastern Asia and North America. Our sediment data collection is heavily biased toward the northern hemisphere, thus more southern hemisphere records are needed to demonstrate GGFMB's robustness in this region.

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Matuyama–Brunhes geomagnetic reversal record and associated key tephra layers in Boso Peninsula: extraction of primary magnetization of geomagnetic fields from mixed magnetic minerals of depositional, diagenesis, and weathering processes

Cited by 2 publications

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Characteristics of the Matuyama‐Brunhes Magnetic Field Reversal Based on a Global Data Compilation

Characteristics of the Matuyama‐Brunhes Magnetic Field Reversal Based on a Global Data Compilation

Global Geomagnetic Field Evolution From 900 to 700 ka Including the Matuyama‐Brunhes Reversal

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