(可雪麗) (原保全) (肖亞敏)
School of Mathematics and Information Science,Henan Polytechnic University,Henan 454000,China E-mail:kexueli123@126.com;bqyuan@hpu.edu.cn;ymxiao106@163.com
Abstract This paper is concerned with a stability problem on perturbations near a physically important steady state solution of the 3D MHD system.We obtain three major results.The first assesses the existence of global solutions with small initial data.Second,we derive the temporal decay estimate of the solution in the L2-norm,where to prove the result,we need to overcome the difficulty caused by the presence of linear terms from perturbation.Finally,the decay rate in L2space for higher order derivatives of the solution is established.
Key words Background magnetic field;MHD equations with perturbation;stability;decay rate
The 3D incompressible magnetohydrodynamic equations can be written as
wherex
∈Randt>
0.U
=U
(x,t
)represents the fluid velocity,B
=B
(x,t
)the magnetic field,andP
=P
(x,t
)the pressure.For simplicity,we set the viscosity coefficientμ
and the magnetic field coefficientν
to 1.The MHD equations(1.1)involve the coupling of the incompressible Navier-Stokes equation and Maxwell’s equation.They play an important role in many fields,such as geophysics,astrophysics,cosmology and engineering(see[3,5,19]).Because of the physical and engineering applications of MHD equations,the mathematical study of them is very important;as a result,the MHD equations have been extensively studied.For instance,G.Duvaut and J.L.Lions[8]obtained the local existence and uniqueness of a solution in the Sobolev spaceH
(R),s>d,
and proved the global existence of the solution for small initial data.M.Sermange and R.Teman[25]further studied the properties of the solutions.Miao,Yuan and Zhang[18]studied the well-posedness of solutions of MHD equations in BMO(R)andbmo
(R),and proved that the solution of the Cauchy problem of MHD with small initial value is globally unique in BMO(R)and locally unique inbmo
(R).Cao,Wu and Yuan[4]studied the 2D incompressible MHD with partial dissipation for data inH
(R),s>
2.Recently,the global regularity issue concerning equations(1.1)has attracted much interest,and considerable results have been obtained(see[9,11,29]).For the 3D equations around the equilibrium state(U
,B
),it is clear thatU
(x,t
)=(0,
0,
0)andB
=(1,
0,
0)are the special solutions of(1.1).The perturbation(u,b
)around this equilibrium withu
?U
?U
,b
?B
?B
obeyswherex
∈R,t>
0.In this paper,inspired by references[23,30],we study the global solutions and decay estimates to equations(1.2)inH
(R).For the global solution of equations(1.2),we refer to[16,27].For the decay estimation of equations(1.2),we refer to[7,15,21,24].However,the classical method does not apply here,due to the appearance of linear terms?
u
and?
b
from the perturbation in equations(1.2).We introduce a diagonalization method to eliminate the linear terms,then we prove the temporal decay estimates by the classical Fourier splitting method.Our main results are stated as follows:First,to prove the global well-posedness of small initial data in Theorem 1.2,we need the local well-posedness result of the strong solution in Proposition 1.1,which can be obtained by a standard procedure with Friedrichs’method.The key estimate is that
The decay rate of the higher order derivative of the solution is also obtained.
Theorem 1.4
Under the assumption of Theorem 1.3,for any integerm
≥0,the small global solution(u,b
)satis fieswhereC
is a constant which depends onm
and the initial data.Λ=√??is de fined in the end of this section.Remark 1.5
The decay rates(1.3)and(1.4)are optimal in the sense that they coincide with the ones of the heat equation.Remark 1.6
For the real numbers>
0,we can also obtain the time decay rate of theL
?norm for thes
-order derivative of the solution by the interpolation relationwithm<s<m
+1,which isThe primary purpose of this section is to give three Lemmas;the first one is the product type estimate,the second and the third are mainly used for the decay estimate of a solution.The detailed processes are as follows:
Lemma 2.1
(Product estimate[13,14,17])Let 1<p<
∞,ands>
0.Then there exists a constantC
such thatWe will use the followingL
estimate of the Fourier transform of the initial datum in a ball(the proof of Lemma 2.2 is based on the Hausdorff-Young theorem;for more details please refer to[12,22,30]):Lemma 2.2
Letu
∈L
(R),1≤p<
2.ThenwhereS
(t
)={ξ
∈R:|ξ
|≤g
(t
)}is a ball withHere,γ>
0 is a constant which will be determined later,and C is a constant which depends uponγ
and theL
norm ofu
.In order to prove Theorem 1.2,we need to calculate the estimates of|u
︿(ξ
)|and|︿b
(ξ
)|,which will play a key role in this paper.For more details,readers can refer to[7,26].Lemma 2.3
Letting(u,b
)∈C
([0,T
];H
(R))be a global solution to the Cauchy problem(1.2)with initial data(u
,b
)∈L
(R)∩H
(R),there exists a constantC>
0 depending only on‖u
‖and‖b
‖such thatProof
We rewrite(1.2)in the following form:HereG
:=?u
·?u
+b
·?b
??p
,F
:=?u
·?b
+b
·?u.
We take the Fourier transform for(2.3)asThen the eigenvalues of matrix A can be calculated as follows:
The associated eigenvectors are
The matrixC
of the eigenvectors and its inverse are given byIntegrating in time,by Duhamel’s formula,we have
fori
=1,
2,
3,and,according to(2.5),we haveWe can get from(2.6)–(2.8)that
Taking the divergence of(1.2),and using the divergence free condition ofu
andb
,we haveSince the Fourier transform is a bounded map fromL
toL
,this leads toSimilarly,by the divergence free condition ofu
andb
,we can obtain thatCombining the estimates(2.12)–(2.16),by the expression formula ofG
andF
,we getInserting(2.17),(2.18)and(2.11)into(2.9),we deduce that
Using an argument similar to(2.10),we have
The proof of Lemma 2.3 is thus completed.
L
inner products of the equations(1.
2)withu
andb
,and adding the results and integrating by parts,we obtainwhere we have used the fact that
u
and Λb
,and integrating over R,we haveNow,we estimateI
–I
.For the termI
,by the divergence free condition ofu
,integration by parts,Lemma 2.1 and‖f
‖≤C
‖f
‖,we obtainFor the termsI
andI
,integrating by parts,we getCombining this with estimate(3.1),we have
Thus,by a continuous extending argument,we get
for all 0<t<
∞.This completes the proof of Theorem 1.1.L
(R)by the classic Fourier splitting method.Proof
Applying Plancherel’s theorem to(3.1),and by splitting the phase space Rinto two time-dependent parts,we getwhereS
(t
)andg
(t
)are de fined in Lemma 2.2,andγ>
0 is a constant which will be determined later.Thus,we obtainMultiplying(4.2)by the integrating factor(t
+1),it follows thatBy Lemma 2.3,we have
Integrating(4.4)in time from 0 tot
leads to the resultInserting estimate(4.6)into(2.19),we can obtain that in the ballS
(t
),Similarly,we obtain
Inserting(4.7)and(4.8)into(4.3),and by Lemma 2.2,we have
This completes the proof of Theorem 1.2.
L
(R)space.Proof
We use the Fourier splitting method again.LetThen Plancherel’s theorem and(5.1)imply that
wherem
≥1 is an integer.Inserting estimate(5.2)into(3.8),it follows thatBy induction,whenm
=1,multiplying both sides of inequality(5.3)by the integrating factor(t
+1)yieldsIntegrating inequality(5.4)from 0 tot
,we haveAssuming that form>
1,Therefore,inserting the above estimate into(5.3),we have
Multiplying both sides of(5.8)by(1+t
),we obtainIntegrating(5.9)on[0,t
],we getTherefore,the proof of Theorem 1.3 is completed.
Acta Mathematica Scientia(English Series)2021年4期