Journal
GEOPHYSICAL JOURNAL INTERNATIONAL
Volume 226, Issue 3, Pages 1897-1919Publisher
OXFORD UNIV PRESS
DOI: 10.1093/gji/ggab161
Keywords
Composition and structure of the core; Core; Dynamo: theories and simulations; Magnetic field variations through time; Numerical modelling
Categories
Funding
- TGCC-Irene KNL [2020-A0070410095]
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This study examines the impact of double-diffusive convection on magnetic field generation in the liquid outer core of the Earth through 3-D global geodynamo models. The findings suggest that the addition of a second buoyancy source facilitates the onset of convection and the transition between dipole-dominated and multipolar dynamos depends on the nature of the buoyancy forcing. Classical parameters expected to govern this transition fail to capture the dipole breakdown, and instead, a scale-dependent analysis of force balance is necessary to understand the dynamics.
Convection in the liquid outer core of the Earth is driven by thermal and chemical perturbations. The main purpose of this study is to examine the impact of double-diffusive convection on magnetic field generation by means of 3-D global geodynamo models, in the so-called lop-heavy' regime of double-diffusive convection, when both thermal and compositional background gradients are destabilizing. Using a linear eigensolver, we begin by confirming that, compared to the standard single-diffusive configuration, the onset of convection is facilitated by the addition of a second buoyancy source. We next carry out a systematic parameter survey by performing 79 numerical dynamo simulations. We show that a good agreement between simulated magnetic fields and the geomagnetic field can be attained for any partitioning of the convective input power between its thermal and chemical components. On the contrary, the transition between dipole-dominated and multipolar dynamos is found to strongly depend on the nature of the buoyancy forcing. Classical parameters expected to govern this transition, such as the local Rossby number a proxy of the ratio of inertial to Coriolis forces or the degree of equatorial symmetry of the flow, fail to capture the dipole breakdown. A scale-dependent analysis of the force balance instead reveals that the transition occurs when the ratio of inertial to Lorentz forces at the dominant length scale reaches 0.5, regardless of the partitioning of the buoyancy power. The ratio of integrated kinetic to magnetic energy E-k/E-m provides a reasonable proxy of this force ratio. Given that E-k/E-m approximate to 10(-4) - 10(-3) in the Earth's core, the geodynamo is expected to operate far from the dipole-multipole transition. It hence appears that the occurrence of geomagnetic reversals is unlikely related to dramatic and punctual changes of the amplitude of inertial forces in the Earth's core, and that another mechanism must be sought.
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