Turbulent convective length scale in planetary cores

Guervilly, Céline; Cardin, Philippe; Schaeffer, Nathanaël

doi:10.1038/s41586-019-1301-5

Cited by 77 publications

(132 citation statements)

References 45 publications

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“…2,20] km for N / f ∈ [1,100], which shows that surface eddies can penetrate relatively far into the thermocline and potentially reach the seabed, especially in weakly stratified waters on the continental shelf. In the Earth's core, if we take ∼ 30 km and Ro ∼ 10 −6 for the diameter and Rossby number of the most intense LSVs, as suggested in a recent study [14], we find h ∼ 2 m for N / f = 1, which is a typical value used in previous works, e.g., Ref. [27].…”

Section: Discussionsupporting

confidence: 62%

“…LSVs studied in this work may be considered a simplified model of cyclones in Earth's atmosphere [63], and in particular of warm-core tropospheric cyclones penetrating into the stratosphere [64], of eddies in Earth's oceans [65,66], and of LSVs in Earth's outer core [14] and stars. Earth's atmosphere, oceans, outer core and stars have different fluid properties, such that the aspect ratio of the stratified cap of LSVs, and the penetration depth, depend on the geophysical or astrophysical fluid of interest.…”

Section: Discussionmentioning

confidence: 99%

“…Planetary atmospheres showcase a wide range of LSVs [12], including long-lived large planetaryscale vortices that control the global circulation and climate (e.g., polar vortices on Earth and Jupiter's Great red spot) as well as smaller cyclones with O(100) km diameter on Earth [13] that can have devastating consequences. Earth's outer core, which is made of turbulent liquid iron that powers the Earth's dynamo, is also expected to feature numerous LSVs of various sizes [14], such as the high-latitude geomagnetic flux patches [15], as well as a large-scale north polar vortex [16]. LSVs are also found in the solar photosphere [17], and are expected to exist in accretion disks [18] and potentially play an important role in planet formation [19].…”

Section: Introductionmentioning

confidence: 99%

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Shape and size of large-scale vortices: A generic fluid pattern in geophysical fluid dynamics

Couston

Lecoanet

Favier

et al. 2020

Phys. Rev. Research

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Planetary rotation organizes fluid motions into coherent, long-lived swirls, known as large-scale vortices (LSVs), which play an important role in the dynamics and long-term evolution of geophysical and astrophysical fluids. Here, using direct numerical simulations, we show that LSVs in rapidly rotating mixed convective and stably stratified fluids, which approximates the two-layer, turbulent-stratified dynamics of many geophysical and astrophysical fluids, have a generic shape and that their size can be predicted. We show that LSVs emerge in the convection zone from upscale energy transfers and can penetrate into the stratified layer. At the convective-stratified interface, the LSV cores have a positive buoyancy anomaly. Due to the thermal wind constraint, this buoyancy anomaly leads to winds in the stratified layer that decay over a characteristic vertical length scale. Thus LSVs take the shape of a depth-invariant cylinder with a finite-size radius in the turbulent layer and of a penetrating half dome in the stratified layer. Importantly, we demonstrate that when LSVs penetrate all the way through the stratified layer and reach a boundary that is no-slip, they saturate by boundary friction. We provide a prediction for the penetration depth and maximum radius of LSVs as a function of the LSV vorticity, the stratified layer depth, and the stratification. Our results, which apply for cyclonic LSVs, suggest that LSVs in slowly rotating stars and Earth's liquid core are confined to the convective layer, while in Earth's atmosphere and oceans they can penetrate far into the stratified layer.

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Section: Discussionsupporting

confidence: 62%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Shape and size of large-scale vortices: A generic fluid pattern in geophysical fluid dynamics

Couston

Lecoanet

Favier

et al. 2020

Phys. Rev. Research

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“…Yet, rapid rotation is known to strongly affect spherical convection (e.g. Guervilly et al 2019), and is therefore believed to strongly modify the effective viscosity when Ro c 1 (Mathis et al 2016). Another complication with incorporating rapid rotation in our model is that the tidal (elliptical) instability can be triggered for large enough β when −1 ≤ Ω or b /Ω s = E/E or b ≤ 3 (Barker et al 2016;Vidal & Cébron 2017).…”

Section: Inclusion Of Weak Rotationmentioning

confidence: 99%

Efficiency of tidal dissipation in slowly rotating fully convective stars or planets

Vidal

Barker

2020

Monthly Notices of the Royal Astronomical Society

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Turbulent convection is thought to act as an effective viscosity in damping equilibrium tidal flows, driving spin and orbital evolution in close convective binary systems. Compared to mixing-length predictions, this viscosity ought to be reduced when the tidal frequency |ωt| exceeds the turnover frequency ωcv of the dominant convective eddies, but the efficiency of this reduction has been disputed. We reexamine this long-standing controversy using direct numerical simulations of an idealized global model. We simulate thermal convection in a full sphere, and externally forced by the equilibrium tidal flow, to measure the effective viscosity νE acting on the tidal flow when |ωt|/ωcv ≳ 1. We demonstrate that the frequency reduction of νE is correlated with the frequency spectrum of the (unperturbed) convection. For intermediate frequencies below those in the turbulent cascade (|ωt|/ωcv ∼ 1 − 5), the frequency spectrum displays an anomalous 1/ωα power law that is responsible for the frequency-reduction νE∝1/|ωt|α, where α < 1 depends on the model parameters. We then get |νE|∝1/|ωt|δ with δ > 1 for higher frequencies, and δ = 2 is obtained for a Kolmogorov turbulent cascade. A generic |νE|∝1/|ωt|2 suppression is next found for higher frequencies within the dissipation range of the convection (but with negative values). Our results indicate that a better knowledge of the frequency spectrum of convection is necessary to accurately predict the efficiency of tidal dissipation in stars and planets resulting from this mechanism.

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“…Thus, the dynamo process is highly complex and the intimate details such as the impact of field strength remain to be elucidated (Fauve & Petrelis, ; Tobias, ). We note that alternative approaches for uncovering the scalings or balances are currently being pursued for the dynamo problem (e.g., Aubert, ; Calkins et al, ; Cattaneo & Hughes, ; Davidson, ; Gastine et al, ; Guervilly et al, ; Tilgner, ).…”

Section: Rbc With An Imposed Magnetic Fieldmentioning

confidence: 99%

Scaling Laws in Rayleigh‐Bénard Convection

Plumley

Julien

2019

Earth and Space Science

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The heat transfer scaling theories for Rayleigh‐Bénard convection (RBC) are reviewed and discussed for configurations with and without rotation and magnetic fields. Scaling laws are a useful tool in studying and characterizing geophysical flows as they provide a basis for extrapolation to extreme parameter regimes that remain unobtainable by current computational and experimental efforts. Specifically, power law scalings that relate the efficiency of the heat transport, as measured by the nondimensional Nusselt number Nu, to the thermal driving are pursued. Relations of the functional form Nu∝false(Rafalse/Racfalse)α are considered. Given the strongly stabilizing influences of rotation and magnetic fields, thermal driving is considered in the context of the supercriticality of the system given by the ratio of the Rayleigh number Ra, measuring the thermal forcing, to the critical Rac, above which convection occurs. Analytical predictions for the exponent α are presented for the regimes of convection, rotating convection, and magnetoconvection, and the scalings are benchmarked against available numerical and experimental results in the accessible regimes. The exponents indicate that the thermal bottleneck to heat transport occurs within the thermal boundary layers for nonrotating RBC and the turbulent interior for rotating RBC. For magnetoconvection, a single exponent of α=1 is obtained for all theories and no bottleneck is identified.

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Turbulent convective length scale in planetary cores

Cited by 77 publications

References 45 publications

Shape and size of large-scale vortices: A generic fluid pattern in geophysical fluid dynamics

Shape and size of large-scale vortices: A generic fluid pattern in geophysical fluid dynamics

Efficiency of tidal dissipation in slowly rotating fully convective stars or planets

Scaling Laws in Rayleigh‐Bénard Convection

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