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Asymptotic behaviour of rotating convection-driven dynamos in the plane layer geometry

Published online by Cambridge University Press:  08 November 2022

Ming Yan
Affiliation:
Department of Physics, University of Colorado, Boulder, CO 80309, USA
Michael A. Calkins*
Affiliation:
Department of Physics, University of Colorado, Boulder, CO 80309, USA
*
Email address for correspondence: michael.calkins@colorado.edu

Abstract

Dynamos driven by rotating convection in the plane layer geometry are investigated numerically for a range of Ekman number ($E$), magnetic Prandtl number ($Pm$) and Rayleigh number ($Ra$). The primary purpose of the investigation is to compare results of the simulations with previously developed asymptotic theory that is applicable in the limit of rapid rotation. We find that all of the simulations are in the quasi-geostrophic regime in which the Coriolis and pressure gradient forces are approximately balanced at leading order, whereas all other forces, including the Lorentz force, act as perturbations. Agreement between simulation output and asymptotic scalings for the energetics, flow speeds, magnetic field amplitude and length scales is found. The transition from large-scale dynamos to small-scale dynamos is well described by the magnetic Reynolds number based on the small convective length scale, $\widetilde {Rm}$, with large-scale dynamos preferred when $\widetilde {Rm} \lesssim O(1)$. The magnitude of the large-scale magnetic field is observed to saturate and become approximately constant with increasing Rayleigh number. Energy spectra show that all length scales present in the flow field and the small-scale magnetic field are consistent with a scaling of $E^{1/3}$, even in the turbulent regime. For a fixed value of $E$, we find that the viscous dissipation length scale is approximately constant over a broad range of $Ra$; the ohmic dissipation length scale is approximately constant within the large-scale dynamo regime, but transitions to a $\widetilde {Rm}^{-1/2}$ scaling in the small-scale dynamo regime.

Information

Type
JFM Papers
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press
Figure 0

Figure 1. Overview of the dynamo regimes, as characterised by the fraction of the mean magnetic energy to the total magnetic energy, $\bar {E}_{mag}/E_{mag}$, in all simulations: (a) $\bar {E}_{mag}/E_{mag}$ vs reduced Rayleigh number, $\widetilde {Ra}$; (b) $\bar {E}_{mag}/E_{mag}$ vs reduced magnetic Reynolds number, $\widetilde {Rm}$. Symbol shape represents different values of the Ekman number ($E$) and colour represents different values of the magnetic ($Pm$): black indicates $Pm=1$; red indicates $Pm=0.3$; green indicates $Pm=0.2$; magenta indicates $Pm=0.1$; blue indicates $Pm=0.05$.

Figure 1

Figure 2. Volumetric renderings of the instantaneous vertical vorticity for $E=10^{-8}$, $Pm=0.1$ and increasing Rayleigh number from left to right: (a) $Ra=1.7Ra_c$ ($\widetilde {Ra}\approx 15$); (b) $Ra=3.5Ra_c$ ($\widetilde {Ra}\approx 30$); (c) $Ra=9Ra_c$ ($\widetilde {Ra}\approx 78$). Red denotes positive (cyclonic) vorticity and blue denotes negative (anti-cyclonic) vorticity.

Figure 2

Figure 3. Top-down view of volumetric renderings of the instantaneous vertical vorticity for a range of Ekman and Rayleigh numbers. The Rayleigh number $\widetilde {Ra}$ increases from left to right and the Ekman number $E$ decreases from top to bottom: (a) $E=10^{-4}$, $Ra=3.5Ra_c$ ($\widetilde {Ra}\approx 31$) and $Pm=1$; (b) $E=10^{-4}$, $Ra=9Ra_c$ ($\widetilde {Ra}\approx 79$) and $Pm=1$; (c) $E=10^{-6}$, $Ra=3Ra_c$ ($\widetilde {Ra}\approx 26$) and $Pm=1$; (d) $E=10^{-6}$, $Ra=9Ra_c$ ($\widetilde {Ra}\approx 78$) and $Pm=1$; (e) $E=10^{-8}$, $Ra=3.5Ra_c$ ($\widetilde {Ra}\approx 30$) and $Pm=0.1$; (f) $E=10^{-8}$, $Ra=9Ra_c$ ($\widetilde {Ra}\approx 78$) and $Pm=0.1$.

Figure 3

Figure 4. Heat transfer data: (a) Nusselt number, $Nu$, vs Rayleigh number, $Ra$; (b) $Nu$ vs reduced Rayleigh number, $\widetilde {Ra} = E^{4/3} Ra$. Symbol shape represents different values of the Ekman number ($E$) and colour represents different values of the magnetic ($Pm$): black indicates $Pm=1$; red indicates $Pm=0.3$; green indicates $Pm=0.2$; magenta indicates $Pm=0.1$; blue indicates $Pm=0.05$.

Figure 4

Figure 5. Dissipation as a function of reduced Rayleigh number $\widetilde {Ra}$ for all simulations: (a) rescaled viscous dissipation, $\varepsilon _u E^{4/3}$; (b) rescaled ohmic dissipation, $\varepsilon _B E^{4/3}$; (c) fraction of ohmic dissipation, $f_{ohm}=\varepsilon _B / (\varepsilon _B+\varepsilon _u)$. Symbol shape represents different values of the Ekman number ($E$) and colour represents different values of the magnetic ($Pm$): black indicates $Pm=1$; red indicates $Pm=0.3$; green indicates $Pm=0.2$; magenta indicates $Pm=0.1$; blue indicates $Pm=0.05$.

Figure 5

Figure 6. Reynolds number and magnetic Reynolds number vs reduced Rayleigh number $\widetilde {Ra}$: (a) large-scale Reynolds number, $Re$; (b) small-scale Reynolds number, $\widetilde {Re} =ReE^{1/3}$; (c) large-scale magnetic Reynolds number, $Rm$; (d) small-scale magnetic Reynolds number, $\widetilde {Rm} =RmE^{1/3}$. Symbol shape represents different values of the Ekman number ($E$) and colour represents different values of the magnetic ($Pm$): black indicates $Pm=1$; red indicates $Pm=0.3$; green indicates $Pm=0.2$; magenta indicates $Pm=0.1$; blue indicates $Pm=0.05$.

Figure 6

Figure 7. Magnetic energy for all simulations: (a) $E_{mag}$ vs $\widetilde {Ra}$; (b) rescaled magnetic energy, $\tilde {E}_{mag}=E_{mag}E^{2/3}$, vs $\widetilde {Ra}$; (c) mean magnetic energy $\bar {E}_{mag}$ vs $\widetilde {Ra}$; (d) rescaled mean magnetic energy $\bar {E}_{mag}E^{2/3}$ vs $\widetilde {Ra}$. Symbol shape represents different values of the Ekman number ($E$) and colour represents different values of the magnetic ($Pm$): black indicates $Pm=1$; red indicates $Pm=0.3$; green indicates $Pm=0.2$; magenta indicates $Pm=0.1$; blue indicates $Pm=0.05$.

Figure 7

Figure 8. Ratio of magnetic energy to kinetic energy for all simulations. Symbol shape represents different values of the Ekman number ($E$) and colour represents different values of the magnetic ($Pm$): black indicates $Pm=1$; red indicates $Pm=0.3$; green indicates $Pm=0.2$; magenta indicates $Pm=0.1$; blue indicates $Pm=0.05$.

Figure 8

Figure 9. Asymptotically rescaled horizontal (a,c) and vertical (b,d) kinetic energy spectra for (a,b) $Ra=1.7Ra_c$ ($\widetilde {Ra}\approx 15$) and (c,d) $Ra=9Ra_c$ ($\widetilde {Ra}\approx 78$). The asymptotically rescaled horizontal wavenumber is defined by $\widetilde {k} = k E^{1/3}$. The vertical dashed line denotes the asymptotically rescaled critical horizontal wavenumber, $\widetilde {k}_c \approx 1.3048$.

Figure 9

Figure 10. Asymptotically rescaled horizontal (a,c) and vertical (b,d) magnetic energy spectra for (a,b) $Ra=1.7Ra_c$ ($\widetilde {Ra}\approx 15$) and (b,d) $Ra=9Ra_c$ ($\widetilde {Ra}\approx 78$). The asymptotically rescaled horizontal wavenumber is defined by $\widetilde {k} = k E^{1/3}$. The vertical dashed line denotes the asymptotically rescaled critical horizontal wavenumber, $\widetilde {k}_c \approx 1.3048$. The colours have the same meaning as defined in figure 9.

Figure 10

Figure 11. Taylor microscales for the velocity and magnetic fields: (a) velocity microscale vs $\widetilde {Ra}$; (b) rescaled velocity microscale $(\tilde {\lambda }_u=\lambda _{u}E^{-1/3})$ vs $\widetilde {Ra}$; (c) magnetic microscale vs $\widetilde {Ra}$; (d) rescaled magnetic microscale $(\tilde {\lambda }_B=\lambda _{B}E^{-1/3})$ vs $\widetilde {Ra}$; (e) rescaled magnetic microscale vs $\widetilde {Rm}$. Symbol shape represents different values of the Ekman number ($E$) and colour represents different values of the magnetic ($Pm$): black indicates $Pm=1$; red indicates $Pm=0.3$; green indicates $Pm=0.2$; magenta indicates $Pm=0.1$; blue indicates $Pm=0.05$.

Figure 11

Figure 12. Global r.m.s. values of all forces for cases with $E=1\times 10^{-8}$ and $Pm=0.1$. (a) The r.m.s. forces in the horizontal direction vs $\widetilde {Ra}$; (b) r.m.s. forces in the vertical direction vs $\widetilde {Ra}$. Note that the data points for the Coriolis and pressure gradient forces are directly on top of one another in panel (a).

Figure 12

Figure 13. Scaling behaviour of (a,b) the viscous force; (c,d) the Lorentz force; and (e,f) the buoyancy force for different Ekman numbers. Panels (a,c,e) show the unscaled forces and (b,d,f) show the asymptotically rescaled forces. The markers have the same meaning in all figures.

Figure 13

Table 1. Details of the numerical simulations for $Pm = 1$, $E = (1\times 10^{-4}, 3\times 10^{-5})$ cases. The non-dimensional parameters are the reduced Rayleigh number $\widetilde {Ra}$, the Nusselt number $Nu$, the Reynolds number $Re$ and the magnetic Reynolds number $Rm$. The spatial resolution is quoted in terms of the de-aliased physical space grid points $N_x \times N_y \times N_z$, where $(N_x,N_y)$ is the horizontal resolution and $N_z$ is the vertical resolution. The numerical timestep size is denoted by $\Delta t$. The magnetic energy is denoted by $E_{mag}$, and the velocity Taylor microscale and magnetic Taylor microscale are denoted by $\lambda _u$ and $\lambda _B$, respectively.

Figure 14

Table 2. Details of the numerical simulations for $Pm = 1$, $E = (1\times 10^{-5},3\times 10^{-6},1\times 10^{-6})$ cases.

Figure 15

Table 3. Details of the numerical simulations for $Pm = 0.3$, $E = (1\times 10^{-6},3\times 10^{-7},1\times 10^{-7})$ cases.

Figure 16

Table 4. Details of the numerical simulations for $Pm = 0.2$, $E = 3\times 10^{-8}$ cases, $Pm = 0.1$, $E = 1\times 10^{-8}$ cases and $Pm = 0.05$, $E = 1\times 10^{-8}$ cases.