Abstract
ABSTRACT The shear-current effect (SCE) of mean-field dynamo theory refers to the combination of a shear flow and a turbulent coefficient β21 with a favourable negative sign for exponential mean-field growth, rather than positive for diffusion. There have been long-standing disagreements among theoretical calculations and comparisons of theory with numerical experiments as to the sign of kinetic ($\beta ^u_{21}$) and magnetic ($\beta ^b_{21}$) contributions. To resolve these discrepancies, we combine an analytical approach with simulations, and show that unlike $\beta ^b_{21}$, the kinetic SCE $\beta ^u_{21}$ has a strong dependence on the kinetic energy spectral index and can transit from positive to negative values at $\mathcal {O}(10)$ Reynolds numbers if the spectrum is not too steep. Conversely, $\beta ^b_{21}$ is always negative regardless of the spectral index and Reynolds numbers. For very steep energy spectra, the positive $\beta ^u_{21}$ can dominate even at energy equipartition urms ≃ brms, resulting in a positive total β21 even though $\beta ^b_{21}\lt 0$. Our findings bridge the gap between the seemingly contradictory results from the second-order-correlation approximation versus the spectral-τ closure, for which opposite signs for $\beta ^u_{21}$ have been reported, with the same sign for $\beta ^b_{21}\lt 0$. The results also offer an explanation for the simulations that find $\beta ^u_{21}\gt 0$ and an inconclusive overall sign of β21 for $\mathcal {O}(10)$ Reynolds numbers. The transient behaviour of $\beta ^u_{21}$ is demonstrated using the kinematic test-field method. We compute dynamo growth rates for cases with or without rotation, and discuss opportunities for further work.
Highlights
1.1 BackgroundDynamos that amplify and sustain magnetic fields are believed to operate in a wide range of astrophysical systems
We examine the sign of both the kinetic and magnetic contributions of β21 at the order linear in the shear rate, and show how they each depend on the Reynolds numbers and the energy spectral indices
A plausible explanation of this discrepancy is that the positive spectral slope at 1 < k < kf yields an effective λ less than its value when dominated by k > kf modes; physically, the effective λ being negative implies that the turbulent transport coefficients measured are really dominated by large-scale motions. β2u1 becomes negative for pure shear flows or positive for Keplerian flows, even if qs slightly exceeds 2. This effect was eliminated from our theoretical calculations, thereby isolating one specific process that can be present in the simulations that is absent in the theory
Summary
Dynamos that amplify and sustain magnetic fields are believed to operate in a wide range of astrophysical systems. 2020, 2021) TFMs all disfavored the SCE and revealed positive values for β21 in both kinetically forced and kinetic-magnetically forced systems These authors argued that the mean-field amplification was more likely the result of the stochastic α effect (Vishniac & Brandenburg 1997; Heinemann et al 2011; Mitra & Brandenburg 2012; Richardson & Proctor 2012; Newton & Kim 2012; Sridhar & Singh 2014; Singh 2016; Jingade et al 2018). A negative β21 for kinetically forced rotating shearing turbulence, as well as for magnetically forced non-rotating shearing turbulence, is obtained These results are in agreement with the SOCA calculation (Squire & Bhattacharjee 2015a), the validity of setting some transport coefficients to zero a priori while solving for others is unclear, an approximation commonly adopted in these works. See Rogachevskii et al (2006), Teed & Proctor (2016), and Singh et al (2017)
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