Global well-posedness of 2D generalized MHD equations with fractional diffusion

Wei, Zhiqiang; Zhu, Weiyi

doi:10.1186/1029-242X-2013-489

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Published: 07 November 2013

Global well-posedness of 2D generalized MHD equations with fractional diffusion

Zhiqiang Wei¹ &
Weiyi Zhu²

Journal of Inequalities and Applications volume 2013, Article number: 489 (2013) Cite this article

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Abstract

In this paper we prove the uniqueness of weak solutions and the global-in-time existence of smooth solutions of the 2D generalized MHD system with fractional diffusion with $\frac{1}{2}$ power.

MSC:35Q30, 76D03, 76D09.

1 Introduction

In this paper, we consider the following 2D generalized MHD system with $0 < α \leq 1$ [1]:

div u = div b = 0,

(1.1)

\partial_{t} u + (u \cdot \nabla) u + \nabla (π + \frac{1}{2} {| b |}^{2}) + {(- Δ)}^{α} u = b \cdot \nabla b,

(1.2)

\partial_{t} b + u \cdot \nabla b - b \cdot \nabla u - Δ b = 0,

(1.3)

(u, b) (t = 0) = (u_{0}, b_{0}) .

(1.4)

Here, u is the fluid velocity field, π is the pressure and b is the magnetic field.

Very recently, Ji [1] used the Fourier series analysis motivated in [2] to prove the global-in-time existence of smooth solutions of problem (1.1)-(1.4) when $\frac{1}{2} < α \leq 1$ , and Ji [1] pointed out that his result did not seem to come directly from the method like energy estimates. In this paper, we use the standard energy method to deal with the case $α = \frac{1}{2}$ ; of course, our method also works when $α > \frac{1}{2}$ . We will prove the following.

Theorem 1.1 Let $α = \frac{1}{2}$ . Let $u_{0}, b_{0} \in H^{1}$ with $div u_{0} = div b_{0} = 0$ in $R^{2}$ . Then problem (1.1)-(1.4) has a unique global-in-time weak solution $(u, b)$ satisfying

(u, b) \in L^{\infty} (0, T; H^{1}), u \in L^{2} (0, T; H^{3 / 2}), b \in L^{2} (0, T; H^{2})

(1.5)

for any $T > 0$ .

Theorem 1.2 Let $α = \frac{1}{2}$ . Let $u_{0}, b_{0} \in H^{s}$ with $s > 1$ and $div u_{0} = div b_{0} = 0$ in $R^{2}$ . Then problem (1.1)-(1.4) has a unique global-in-time smooth solution $(u, b)$ satisfying

u, b \in L^{\infty} (0, T; H^{s}), u \in L^{2} (0, T; H^{s + \frac{1}{2}}), b \in L^{2} (0, T; H^{s + 1})

(1.6)

for any $T > 0$ .

For 3D case and other related problems, we refer to [3, 4].

Our proof will use the following commutator estimates due to Kato and Ponce [5]:

{∥ Λ^{s} (f g) - f Λ^{s} g ∥}_{L^{p}} \leq C ({∥ \nabla f ∥}_{L^{p_{1}}} {∥ Λ^{s - 1} g ∥}_{L^{q_{1}}} + {∥ Λ^{s} f ∥}_{L^{p_{2}}} {∥ g ∥}_{L^{q_{2}}}),

(1.7)

with $s \geq 1$ , $Λ : = {(- Δ)}^{1 / 2}$ and $\frac{1}{p} = \frac{1}{p_{1}} + \frac{1}{q_{1}} = \frac{1}{p_{2}} + \frac{1}{q_{2}}$ .

2 Proof of Theorem 1.1

This section is devoted to the proof of Theorem 1.1. The global-in-time existence of weak solutions satisfying (1.5) was proved in [1, 6], we only need to show the uniqueness. Let $(u_{i}, π_{i}, b_{i})$ ( $i = 1, 2$ ) be two weak solutions of problem (1.1)-(1.4). We define

δ u : = u_{1} - u_{2}, δ π : = π_{1} - π_{2}, δ b : = b_{1} - b_{2} .

Then it follows from (1.1)-(1.3) that

div δ u = 0, div δ b = 0,

(2.1)

\begin{aligned} \partial_{t} δ u + u_{1} \cdot \nabla δ u + δ u \cdot \nabla u_{2} + \nabla (π + \frac{1}{2} (b_{1}^{2} - b_{2}^{2})) + {(- Δ)}^{1 / 2} δ u \\ = b_{1} \cdot \nabla δ b + δ b \cdot \nabla b_{2}, \end{aligned}

(2.2)

\partial_{t} δ b + u_{1} \cdot \nabla δ b + δ u \cdot \nabla b_{2} - b_{1} \cdot \nabla δ u - δ b \cdot \nabla u_{2} - Δ δ b = 0 .

(2.3)

Testing (2.2) by δu and using (1.1) and (2.1), we see that

\begin{aligned} \frac{1}{2} \frac{d}{d t} \int {| δ u |}^{2} d x + \int {| Λ^{1 / 2} δ u |}^{2} d x = & - \int δ u \cdot \nabla u_{2} \cdot δ u d x \\ + \int b_{1} \cdot \nabla δ b \cdot δ u d x + \int δ b \cdot \nabla b_{2} \cdot δ u d x \\ = : & I_{1} + I_{2} + I_{3} . \end{aligned}

(2.4)

Testing (2.3) by δb and using (1.1) and (2.1), we find that

\begin{aligned} \frac{1}{2} \frac{d}{d t} \int {| δ b |}^{2} d x + \int {| \nabla δ b |}^{2} d x = & - \int δ u \cdot \nabla b_{2} \cdot δ b d x \\ + \int b_{1} \cdot \nabla δ u \cdot δ b d x + \int δ b \cdot \nabla u_{2} \cdot δ b d x \\ = : & I_{4} + I_{5} + I_{6} . \end{aligned}

(2.5)

In the following calculations, we use the Sobolev embedding ${\dot{H}}^{1 / 2} \subset L^{4}$ and the Gagliardo-Nirenberg inequalities

{∥ w ∥}_{L^{8 / 3}}^{2} \leq C {∥ w ∥}_{L^{2}} {∥ Λ^{1 / 2} w ∥}_{L^{2}},

(2.6)

{∥ w ∥}_{L^{4}}^{2} \leq C {∥ w ∥}_{L^{2}} {∥ \nabla w ∥}_{L^{2}} .

(2.7)

Using (1.1), (2.1), (1.5), (2.6) and (2.7), we bound $I_{1}$ , $I_{2} + I_{5}$ , $I_{3} + I_{4}$ and $I_{6}$ as follows:

\begin{matrix} I_{1} \leq {∥ \nabla u_{2} ∥}_{L^{4}} {∥ δ u ∥}_{L^{8 / 3}}^{2} \leq C {∥ u_{2} ∥}_{{\dot{H}}^{3 / 2}} {∥ δ u ∥}_{L^{2}} {∥ Λ^{1 / 2} δ u ∥}_{L^{2}} \\ \leq \frac{1}{16} {∥ Λ^{1 / 2} δ u ∥}_{L^{2}}^{2} + C {∥ u_{2} ∥}_{{\dot{H}}^{3 / 2}}^{2} {∥ δ u ∥}_{L^{2}}^{2}, \\ I_{2} + I_{5} = 0, \\ I_{3} + I_{4} \leq C {∥ \nabla b_{2} ∥}_{L^{4}} {∥ δ u ∥}_{L^{2}} {∥ δ b ∥}_{L^{4}} \\ \leq C {∥ \nabla b_{2} ∥}_{L^{4}} {∥ δ u ∥}_{L^{2}} {∥ δ b ∥}_{L^{2}}^{1 / 2} {∥ \nabla δ b ∥}_{L^{2}}^{1 / 2} \\ \leq \frac{1}{16} {∥ \nabla δ b ∥}_{L^{2}}^{2} + C {∥ δ u ∥}_{L^{2}}^{2} + C {∥ \nabla b_{2} ∥}_{L^{4}}^{2} {∥ δ b ∥}_{L^{2}}^{2}, \\ I_{6} \leq {∥ \nabla u_{2} ∥}_{L^{2}} {∥ δ b ∥}_{L^{4}}^{2} \leq C {∥ δ b ∥}_{L^{4}}^{2} \leq C {∥ δ b ∥}_{L^{2}} {∥ \nabla δ b ∥}_{L^{2}} \\ \leq \frac{1}{16} {∥ \nabla δ b ∥}_{L^{2}}^{2} + C {∥ δ b ∥}_{L^{2}}^{2} . \end{matrix}

Adding up (2.4) and (2.5) and using the above estimates, we conclude that

\begin{matrix} \frac{1}{2} \frac{d}{d t} \int ({| δ u |}^{2} + {| δ b |}^{2}) d x \\ \leq C {∥ u_{2} ∥}_{{\dot{H}}^{3 / 2}}^{2} {∥ δ u ∥}_{L^{2}}^{2} + C {∥ δ u ∥}_{L^{2}}^{2} + C {∥ \nabla b_{2} ∥}_{L^{4}}^{2} {∥ δ b ∥}_{L^{2}}^{2} + C {∥ δ b ∥}_{L^{2}}^{2}, \end{matrix}

which gives

δ u = δ b = 0 .

This completes the proof.

3 Proof of Theorem 1.2

This section is devoted to the proof of Theorem 1.2. We only need to prove a priori estimates (1.6) for simplicity.

First, we have (1.5).

Applying $Λ^{s}$ to (1.2), testing by $Λ^{s} u$ and using (1.1), we see that

\begin{aligned} \frac{1}{2} \frac{d}{d t} \int {| Λ^{s} u |}^{2} d x + \int {| Λ^{s + \frac{1}{2}} u |}^{2} d x \\ = - \int (Λ^{s} (u \cdot \nabla u) - u \nabla Λ^{s} u) Λ^{s} u d x \\ + \int (Λ^{s} (b \cdot \nabla b) - b \cdot \nabla Λ^{s} b) Λ^{s} u d x + \int b \cdot \nabla Λ^{s} b \cdot Λ^{s} u d x \\ = : J_{1} + J_{2} + J_{3} . \end{aligned}

(3.1)

Applying $Λ^{s}$ to (1.3), testing by $Λ^{s} b$ and using (1.1), we find that

\begin{aligned} \frac{1}{2} \frac{d}{d t} \int {| Λ^{s} b |}^{2} d x + \int {| Λ^{s + 1} b |}^{2} d x \\ = - \int (Λ^{s} (u \cdot \nabla b) - u \cdot \nabla Λ^{s} b) Λ^{s} b d x \\ + \int (Λ^{s} (b \cdot \nabla u) - b \cdot \nabla Λ^{s} u) Λ^{s} b d x + \int b \cdot \nabla Λ^{s} u \cdot Λ^{s} b d x \\ = : J_{4} + J_{5} + J_{6} . \end{aligned}

(3.2)

Using (1.7), (2.6), (2.7) and (1.5), we bound $J_{1}$ , $J_{2}$ , $J_{3} + J_{6}$ , $J_{4}$ and $J_{5}$ as follows:

\begin{matrix} J_{1} \leq C {∥ \nabla u ∥}_{L^{4}} {∥ Λ^{s} u ∥}_{L^{8 / 3}}^{2} \\ \leq C {∥ u ∥}_{{\dot{H}}^{3 / 2}} {∥ Λ^{s} u ∥}_{L^{2}} {∥ Λ^{s + \frac{1}{2}} u ∥}_{L^{2}} \\ \leq \frac{1}{8} {∥ Λ^{s + \frac{1}{2}} u ∥}_{L^{2}}^{2} + C {∥ u ∥}_{{\dot{H}}^{3 / 2}}^{2} {∥ Λ^{s} u ∥}_{L^{2}}^{2}, \\ J_{2} \leq C {∥ \nabla b ∥}_{L^{4}} {∥ Λ^{s} b ∥}_{L^{2}} {∥ Λ^{s} u ∥}_{L^{4}} \\ \leq C {∥ \nabla b ∥}_{L^{4}} {∥ Λ^{s} b ∥}_{L^{2}} {∥ Λ^{s + \frac{1}{2}} u ∥}_{L^{2}} \\ \leq \frac{1}{8} {∥ Λ^{s + \frac{1}{2}} u ∥}_{L^{2}}^{2} + C {∥ \nabla b ∥}_{L^{4}}^{2} {∥ Λ^{s} b ∥}_{L^{2}}^{2}, \\ J_{3} + J_{6} = 0, \\ J_{4}, J_{5} \leq C {∥ \nabla u ∥}_{L^{2}} {∥ Λ^{s} b ∥}_{L^{4}}^{2} + C {∥ \nabla b ∥}_{L^{8 / 3}} {∥ Λ^{s} u ∥}_{L^{8 / 3}} {∥ Λ^{s} b ∥}_{L^{4}} \\ \leq C {∥ Λ^{s} b ∥}_{L^{4}}^{2} + C {∥ \nabla b ∥}_{L^{8 / 3}}^{2} {∥ Λ^{s} u ∥}_{L^{8 / 3}}^{2} \\ \leq C {∥ Λ^{s} b ∥}_{L^{2}} {∥ Λ^{s + 1} b ∥}_{L^{2}} + C {∥ \nabla b ∥}_{L^{8 / 3}}^{2} {∥ Λ^{s} u ∥}_{L^{2}} {∥ Λ^{s + \frac{1}{2}} u ∥}_{L^{2}} \\ \leq \frac{1}{8} {∥ Λ^{s + 1} b ∥}_{L^{2}}^{2} + \frac{1}{8} {∥ Λ^{s + \frac{1}{2}} u ∥}_{L^{2}}^{2} + C {∥ Λ^{s} b ∥}_{L^{2}}^{2} + C {∥ \nabla b ∥}_{L^{8 / 3}}^{4} {∥ Λ^{s} u ∥}_{L^{2}}^{2} . \end{matrix}

Adding up (3.1) and (3.2) and using the above estimates, we arrive at

\begin{matrix} \frac{d}{d t} \int ({| Λ^{s} u |}^{2} + {| Λ^{s} b |}^{2}) d x + \int ({| Λ^{s + \frac{1}{2}} u |}^{2} + {| Λ^{s + 1} b |}^{2}) d x \\ \leq C {∥ u ∥}_{{\dot{H}}^{3 / 2}}^{2} {∥ Λ^{s} u ∥}_{L^{2}}^{2} + C {∥ \nabla b ∥}_{L^{4}}^{2} {∥ Λ^{s} b ∥}_{L^{2}}^{2} + C {∥ Λ^{s} b ∥}_{L^{2}}^{2} + C {∥ \nabla b ∥}_{L^{8 / 3}}^{4} {∥ Λ^{s} u ∥}_{L^{2}}^{2}, \end{matrix}

which yields (1.6).

This completes the proof.

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School of Mathematics and Information Sciences, North China University of Water Resources and Electric Power, Zhengzhou, 450011, P.R. China
Zhiqiang Wei
Department of Mathematics, Zhejiang Normal University, Jinhua, Zhejiang, 321004, P.R. China
Weiyi Zhu

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ZW proposed the problems and finished the whole manuscript. WZ modified the proofs. All authors read and approved the final manuscript.

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Wei, Z., Zhu, W. Global well-posedness of 2D generalized MHD equations with fractional diffusion. J Inequal Appl 2013, 489 (2013). https://doi.org/10.1186/1029-242X-2013-489

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Received: 09 August 2013
Accepted: 30 August 2013
Published: 07 November 2013
DOI: https://doi.org/10.1186/1029-242X-2013-489

Global well-posedness of 2D generalized MHD equations with fractional diffusion

Abstract

1 Introduction

2 Proof of Theorem 1.1

3 Proof of Theorem 1.2

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