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Large-scale palaeoflow at the top of Earth's core

Suttie, Neil LU orcid ; Nilsson, Andreas LU ; Gillet, Nicolas and Dumberry, Mathieu (2025) In Earth and Planetary Science Letters 652.
Abstract

A number of recent studies have made use of statistics derived from geodynamo simulations to constrain the flow at the top of the Earth's core. Here we adapt these methods to infer possible core surface flow solutions over the past 9000 years, using a low degree geomagnetic field model, based on archaeomagnetic and sedimentary archives. Despite the low spatial resolution of the field model, we find that the largest scale aspects of the recovered flow agree well with those derived from historical field models. In particular we see the growth of an eccentric planetary gyre over the past 400 years and find that a similar feature appears on bimillennial timescales, concurrent with pulses in the zonal flow. In the flow model vigorous gyre... (More)

A number of recent studies have made use of statistics derived from geodynamo simulations to constrain the flow at the top of the Earth's core. Here we adapt these methods to infer possible core surface flow solutions over the past 9000 years, using a low degree geomagnetic field model, based on archaeomagnetic and sedimentary archives. Despite the low spatial resolution of the field model, we find that the largest scale aspects of the recovered flow agree well with those derived from historical field models. In particular we see the growth of an eccentric planetary gyre over the past 400 years and find that a similar feature appears on bimillennial timescales, concurrent with pulses in the zonal flow. In the flow model vigorous gyre structures are not persistent but appear as transient features with durations of a few hundred years. The zonal flow is westward over the entire period with a mean value of 0.09° /yr. Finally, we consider the variations in length-of-day that are implied by the flow model under the assumption of geostrophy, and compare the total clock error with that inferred from records of historical solar eclipses. Good agreement is found between the two series of mantle rotation for at least the past 1200 years, with anomalously slow mantle rotation coupled with reduced westward zonal flow. Further back in time a rigorous assessment is hard to make, owing to uncertainty surrounding the exact locations of eclipses.

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author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Core flow, Geomagnetism, Length-of-day
in
Earth and Planetary Science Letters
volume
652
article number
119185
publisher
Elsevier
external identifiers
  • scopus:85213557687
ISSN
0012-821X
DOI
10.1016/j.epsl.2024.119185
language
English
LU publication?
yes
additional info
Publisher Copyright: © 2024
id
0403a2e0-2f1e-446a-b455-dfc09683c910
date added to LUP
2025-03-14 10:57:33
date last changed
2025-04-04 15:02:52
@article{0403a2e0-2f1e-446a-b455-dfc09683c910,
  abstract     = {{<p>A number of recent studies have made use of statistics derived from geodynamo simulations to constrain the flow at the top of the Earth's core. Here we adapt these methods to infer possible core surface flow solutions over the past 9000 years, using a low degree geomagnetic field model, based on archaeomagnetic and sedimentary archives. Despite the low spatial resolution of the field model, we find that the largest scale aspects of the recovered flow agree well with those derived from historical field models. In particular we see the growth of an eccentric planetary gyre over the past 400 years and find that a similar feature appears on bimillennial timescales, concurrent with pulses in the zonal flow. In the flow model vigorous gyre structures are not persistent but appear as transient features with durations of a few hundred years. The zonal flow is westward over the entire period with a mean value of 0.09° /yr. Finally, we consider the variations in length-of-day that are implied by the flow model under the assumption of geostrophy, and compare the total clock error with that inferred from records of historical solar eclipses. Good agreement is found between the two series of mantle rotation for at least the past 1200 years, with anomalously slow mantle rotation coupled with reduced westward zonal flow. Further back in time a rigorous assessment is hard to make, owing to uncertainty surrounding the exact locations of eclipses.</p>}},
  author       = {{Suttie, Neil and Nilsson, Andreas and Gillet, Nicolas and Dumberry, Mathieu}},
  issn         = {{0012-821X}},
  keywords     = {{Core flow; Geomagnetism; Length-of-day}},
  language     = {{eng}},
  month        = {{02}},
  publisher    = {{Elsevier}},
  series       = {{Earth and Planetary Science Letters}},
  title        = {{Large-scale palaeoflow at the top of Earth's core}},
  url          = {{http://dx.doi.org/10.1016/j.epsl.2024.119185}},
  doi          = {{10.1016/j.epsl.2024.119185}},
  volume       = {{652}},
  year         = {{2025}},
}