Asymptotic Stability of Couette Flow in a Strong Uniform Magnetic Field for the Euler-MHD System

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-05-17 DOI:10.1007/s00205-024-01996-8

Weiren Zhao, Ruizhao Zi

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Abstract

In this paper, we prove the asymptotic stability of Couette flow in a strong uniform magnetic field for the Euler-MHD system, when the perturbations are in Gevrey-$\frac{1}{s}$, $(\frac{1}{2}<s\leqq 1)$ and of size smaller than the resistivity coefficient $\mu $. More precisely, we prove that

(1)
the $\mu ^{-\frac{1}{3}}$-amplification of the perturbed vorticity, namely, the size of the vorticity grows from $\Vert \omega _{\textrm{in}}\Vert _{\mathcal {G}^{\lambda _{0}}}\lesssim \mu $ to $\Vert \omega _{\infty }\Vert _{\mathcal {G}^{\lambda '}}\lesssim \mu ^{\frac{2}{3}}$;
(2)
the polynomial decay of the perturbed current density, namely, $\left\| j_{\ne }\right\| _{L^2}\lesssim \frac{c_0 }{\langle t\rangle ^2 }\min \left\{ \mu ^{-\frac{1}{3}},\langle t \rangle \right\} $;
(3)
and the damping for the perturbed velocity and magnetic field, namely,
$$\begin{aligned} \left\| (u^1_{\ne },b^1_{\ne })\right\| _{L^2}\lesssim \frac{c_0\mu }{\langle t\rangle }\min \left\{ \mu ^{-\frac{1}{3}},\langle t \rangle \right\} , \quad \left\| (u^2,b^2)\right\| _{L^2}\lesssim \frac{c_0\mu }{\langle t\rangle ^2 }\min \left\{ \mu ^{-\frac{1}{3}},\langle t \rangle \right\} . \end{aligned}$$

We also confirm that the strong uniform magnetic field stabilizes the Euler-MHD system near Couette flow.

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欧拉-MHD 系统在强均匀磁场中耦合流的渐近稳定性

在本文中，我们证明了欧拉-MHD系统在强均匀磁场中Couette流的渐近稳定性，当扰动在Gevrey-(\frac{1}{s}\)、$(\frac{1}{2}<s\leqq 1)$并且大小小于电阻率系数$\mu $时。更准确地说，我们证明了：(1)扰动涡度的（\mu ^{-\frac{1}{3}}\）放大，即、涡度的大小从(\Vert \omega _{textrm{in}}\Vert _{\mathcal {G}^{\lambda _{0}}}lesssim \mu \)增长到(\Vert \omega _{infty }\Vert _{\mathcal {G}^{\lambda '}}lesssim \mu ^{\frac{2}{3}}\)；(2)the polynomial decay of the perturbed current density, namely, $\left\| j_{\ne }\right| _{L^2}\lesssim \frac{c_0 }{\langle t\rangle ^2 }\min \left\{ \mu ^{-\frac{1}{3}}, \langle t\rangle \right\});(3)and the polynomial decay of the perturbed current density, namely, \(\left\| j_{\ne }\right| _{L^2}\lesssim \frac{c_0 }{\langle t\rangle ^2 }\min$；(3)扰动速度和磁场的阻尼，即 $$\begin{aligned}\(u^1_{\ne },b^1_{\ne })\right} _{L^2}\lesssim \frac{c_0\mu }\{langle t\rangle }\min \left\{ \mu ^{-\frac{1}{3}},\langle t\rangle \right\}, quad \left\| (u^2,b^2)\right\| _{L^2}\lesssim \frac{c_0\mu }{langle t\rangle ^2 }\min \left\{ \mu ^{-\frac{1}{3}},\langle t\rangle \right\} .\end{aligned}$$ 我们还证实了强均匀磁场能使欧拉-MHD 系统在库特流附近保持稳定。

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