Fossil field decay due to nonlinear tides in massive binaries

Vidal, Jérémie; Cébron, David; ud‐Doula, Asif; Alécian, E.

doi:10.1051/0004-6361/201935658

Cited by 28 publications

(38 citation statements)

References 213 publications

(475 reference statements)

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“…2015; Vidal et al. 2019), where is here a typical measure of the boundary (equatorial or polar) ellipticity. Several secondary instability mechanisms could then occur to sustain bulk-driven zonal flows.…”

Section: Discussionmentioning

confidence: 99%

Mean zonal flows induced by weak mechanical forcings in rotating spheroids

et al. 2021

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Section: Discussionmentioning

confidence: 99%

Mean zonal flows induced by weak mechanical forcings in rotating spheroids

et al. 2021

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“…Non-linear tidal flows can also be triggered in rapidly rotating interiors for sufficiently large tidal deformations (such as the elliptical (tidal) instability, e.g. Barker et al 2016;Vidal & Cébron 2017), which could enhance tidal dissipation for the shortest orbital periods (Barker 2016;Vidal et al 2018Vidal et al , 2019. Understanding the interplay of these flows with convection also deserves future work.…”

Section: Discussionmentioning

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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“…While this may be a valid threshold for convective dynamos, it is less clear that it applies for a mechanical dynamo driven by precession. Even if no heat flow escapes the core, and the latter is thermally stratified, tidal instabilities can still be generated (e.g., Cébron et al, 2010; Vidal et al, 2018; 2019), and the additional mechanical forcing at the boundary from the precessing mantle may be capable to drive a dynamo. Nevertheless, there must be a threshold value otherwise a precession dynamo would still be operating in the Moon today.…”

Section: Theorymentioning

confidence: 99%

A Past Lunar Dynamo Thermally Driven by the Precession of Its Inner Core

Stys

Dumberry

2020

JGR Planets

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The Cassini state equilibrium associated with the precession of the Moon predicts that the mantle, fluid core, and solid inner core precess at different angles. We present estimates of the dissipation from viscous friction associated with the differential precession at the core‐mantle boundary (CMB), Qcmb, and at the inner core boundary (ICB), Qicb, as a function of the evolving lunar orbit. We focus on the latter and show that, provided the inner core was larger than 100 km, Qicb may have been as high as 1010–1011 W for most of the lunar history for a broad range of core density models. This is larger than the power required to maintain the fluid core in an adiabatic state; therefore, the heat released by the differential precession at the ICB can drive a past lunar dynamo by thermal convection. This dynamo can outlive the dynamo from precession at the CMB and may have shut off only relatively recently. Estimates of the magnetic field strength at the lunar surface are of the order of a few μT, compatible with the lunar paleomagnetic intensities recorded after 3 Ga. We further show that it is possible that a transition of the Cassini state associated with the inner core may have occurred as a result of the evolution of the lunar orbit. The heat flux associated with Qicb can be of the order of a few mW m−2, which should slow down inner core growth and be included in thermal evolution models of the lunar core.

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Fossil field decay due to nonlinear tides in massive binaries

Cited by 28 publications

References 213 publications

Mean zonal flows induced by weak mechanical forcings in rotating spheroids

Mean zonal flows induced by weak mechanical forcings in rotating spheroids

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

A Past Lunar Dynamo Thermally Driven by the Precession of Its Inner Core

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