The formation and evolution of the Earth’s inner core

Alfred J. Wilson; Christopher J. Davies; Andrew M. Walker; Monica Pozzo; Dario Alfè; Arwen Deuss

doi:10.1038/s43017-024-00639-6

The formation and evolution of the Earth’s inner core

Alfred J. Wilson^*, Christopher J. Davies, Andrew M. Walker, Monica Pozzo, Dario Alfè, Arwen Deuss

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

Abstract

The growth of the solid inner core from the liquid outer core provides crucial power for generating the geomagnetic field. However, the traditional view of inner core growth does not include the physical requirement that liquids must be supercooled below the melting point before freezing can begin. In this Review, we explore the impact of supercooling the Earth’s core on inner core formation, growth and dynamics, and the interpretation of seismic and palaeomagnetic observations. Mineral physics calculations suggest that at least 450 K of supercooling is needed to spontaneously nucleate the inner core. However, when satisfying inferences from geophysical constraints, the maximum available supercooling is estimated at 420 K and more probably <100 K. Supercooling the Earth’s core requires that the inner core had at least two growth regimes. The first regime is a rapid phase that freezes supercooled liquids at rates comparable to outer core dynamics (cm yr⁻¹), followed by the second regime that is a traditional in-equilibrium growth phase proportional to the cooling rate of the core (mm yr⁻¹). Future research should seek evidence for rapid growth in the palaeomagnetic and seismic records and the mechanisms that produce deformation texture, particularly those owing to heterogeneous inner core growth, inner core convection, and coupling between freezing and the magnetic field.

Original language	English
Pages (from-to)	140-154
Number of pages	15
Journal	Nature Reviews Earth and Environment
Volume	6
Issue number	2
DOIs	https://doi.org/10.1038/s43017-024-00639-6
Publication status	Published - Feb 2025

Bibliographical note

Publisher Copyright:
© Crown 2025.

Funding

A.J.W., A.M.W., D.A., M.P. and C.J.D. acknowledge support from a Natural Environment Research Council (NERC) grant, reference NE/T000228/1. A.J.W. and C.J.D. also acknowledge NERC grant number NE/V010867/1, A.M.W. and C.J.D. acknowledge NERC grant number NE/T004835/1, and D.A. and M.P. acknowledge NERC grant numbers NE/M000990/1 and NE/R000425/1. M.P. acknowledges the funding from the DOME 4.0 project from the European Union's Horizon 2020 Research and Innovation Programme under grant agreement number 953163. A.D. acknowledges support from European Research Council (ERC) under the European Union's Horizon 2020 Research and Innovation Programme (grant agreement number 681535 - ATUNE) and a Vici award number 016.160.310/526 from the Netherlands Organisation for Scientific Research (NWO). The authors thank M. Lasbleis for her helpful discussion on the dynamics of the inner core.

Funders	Funder number
Natural Environment Research Council (NERC)	NE/T000228/1
NERC	NE/M000990/1, NE/R000425/1
DOME 4.0 project from the European Union	953163
European Research Council (ERC) under the European Union	681535 - ATUNE, 016.160.310/526
Netherlands Organisation for Scientific Research (NWO)

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title = "The formation and evolution of the Earth{\textquoteright}s inner core",

abstract = "The growth of the solid inner core from the liquid outer core provides crucial power for generating the geomagnetic field. However, the traditional view of inner core growth does not include the physical requirement that liquids must be supercooled below the melting point before freezing can begin. In this Review, we explore the impact of supercooling the Earth{\textquoteright}s core on inner core formation, growth and dynamics, and the interpretation of seismic and palaeomagnetic observations. Mineral physics calculations suggest that at least 450 K of supercooling is needed to spontaneously nucleate the inner core. However, when satisfying inferences from geophysical constraints, the maximum available supercooling is estimated at 420 K and more probably <100 K. Supercooling the Earth{\textquoteright}s core requires that the inner core had at least two growth regimes. The first regime is a rapid phase that freezes supercooled liquids at rates comparable to outer core dynamics (cm yr−1), followed by the second regime that is a traditional in-equilibrium growth phase proportional to the cooling rate of the core (mm yr−1). Future research should seek evidence for rapid growth in the palaeomagnetic and seismic records and the mechanisms that produce deformation texture, particularly those owing to heterogeneous inner core growth, inner core convection, and coupling between freezing and the magnetic field.",

author = "Wilson, \{Alfred J.\} and Davies, \{Christopher J.\} and Walker, \{Andrew M.\} and Monica Pozzo and Dario Alf{\`e} and Arwen Deuss",

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AU - Alfè, Dario

AU - Deuss, Arwen

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N2 - The growth of the solid inner core from the liquid outer core provides crucial power for generating the geomagnetic field. However, the traditional view of inner core growth does not include the physical requirement that liquids must be supercooled below the melting point before freezing can begin. In this Review, we explore the impact of supercooling the Earth’s core on inner core formation, growth and dynamics, and the interpretation of seismic and palaeomagnetic observations. Mineral physics calculations suggest that at least 450 K of supercooling is needed to spontaneously nucleate the inner core. However, when satisfying inferences from geophysical constraints, the maximum available supercooling is estimated at 420 K and more probably <100 K. Supercooling the Earth’s core requires that the inner core had at least two growth regimes. The first regime is a rapid phase that freezes supercooled liquids at rates comparable to outer core dynamics (cm yr−1), followed by the second regime that is a traditional in-equilibrium growth phase proportional to the cooling rate of the core (mm yr−1). Future research should seek evidence for rapid growth in the palaeomagnetic and seismic records and the mechanisms that produce deformation texture, particularly those owing to heterogeneous inner core growth, inner core convection, and coupling between freezing and the magnetic field.

AB - The growth of the solid inner core from the liquid outer core provides crucial power for generating the geomagnetic field. However, the traditional view of inner core growth does not include the physical requirement that liquids must be supercooled below the melting point before freezing can begin. In this Review, we explore the impact of supercooling the Earth’s core on inner core formation, growth and dynamics, and the interpretation of seismic and palaeomagnetic observations. Mineral physics calculations suggest that at least 450 K of supercooling is needed to spontaneously nucleate the inner core. However, when satisfying inferences from geophysical constraints, the maximum available supercooling is estimated at 420 K and more probably <100 K. Supercooling the Earth’s core requires that the inner core had at least two growth regimes. The first regime is a rapid phase that freezes supercooled liquids at rates comparable to outer core dynamics (cm yr−1), followed by the second regime that is a traditional in-equilibrium growth phase proportional to the cooling rate of the core (mm yr−1). Future research should seek evidence for rapid growth in the palaeomagnetic and seismic records and the mechanisms that produce deformation texture, particularly those owing to heterogeneous inner core growth, inner core convection, and coupling between freezing and the magnetic field.

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DO - 10.1038/s43017-024-00639-6

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ER -

The formation and evolution of the Earth’s inner core

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