YANG Jian
School of Mathematical Sciences,University of Jinan,Jinan 250022,China.
Abstract. We investigate a blowup problem of a reaction-advection-diffusion equation with double free boundaries and aim to use the dynamics of such a problem to describe the heat transfer and temperature change of a chemical reaction in advective environment with the free boundary representing the spreading front of the heat.We study the influence of the advection on the blowup properties of the solutions and conclude that large advection is not favorable for blowup.Moreover,we give the decay estimates of solutions and the two free boundaries converge to a finite limit for small initial data.
Key Words: Nonlinear reaction-advection-diffusion equation;one-phase Stefan problem;decay;blowup.
We study the blowup solution for the following reaction-advection-diffusion equation
wherex=g(t),h(t)are free boundaries to be determined.p>1 andh0,µ,βare some given positive constants.The initial functionu0satisfies
Problem(1.1)may be viewed as describing the heat transfer and temperature change in chemical reaction,u(t,x)may represent the temperature over a one-dimensional region and the initial functionu0(x)stands for the temperature distribution in each point at the initial time which occupy an initial region(-h0,h0).
Whenβ=0(i.e.there is no advection in the environment),the qualitative properties of the problem(1.1)were studied by Souplet and his collaborators[1-4],they study the blowup phenomenon of reaction-diffusion equation with a free boundary and prove the solution blows up in finite time inL∞norm and all global solutions are bounded and decay uniformly to 0.
Our concern is to discuss the blowup properties of the solutions of (1.1) withβ >0,which means the heat transfer is affected by advection.In the process of chemical reactions,we may use the free boundary to represent the spreading front of the heat.We know that chemical reactions with a high initial temperature produce a lot of heat,which will increase the temperature of chemical reactions,thus accelerating the rate of chemical reactions,and as a result making the reaction temperature higher and higher and even converge to infinity in finite time.Mathematically,it means the solutions will blow up.In the field of physics [5],the advective heat transfer is an important physical process.Advective heat transfer is caused by relative displacement of particles during fluid movement.In some cases,the fluid motion that occurs under the influence of external forces is called forced motion of fluid.Heat transfer and fluid motion are inextricably linked because of advective heat transfer.Therefore,advection due to external forces is a very important factor affecting heat transfer.
The main purpose of this paper is to investigate the effect of the advection on the properties of blowup solution of(1.1)provided the initial datum has compact supports.Our results indicate that larger advection makes blowup more difficult.We denoteT*as the blowup time throughout this paper:
IfT*<∞,one has
The plan of the paper is as follows: some preliminary results,including the existence and the comparison principle of (1.1) are gathered in Section 2.Blowup and vanishing results are proved in Section 3.
We begin by recalling the local existence and uniqueness result which can be proved by the similar method as in[6-8].
Theorem 2.1.For any u0satisfying(1.2)and any α∈(0,1),there exists a positive number T>0such that problem(1.1)admits a unique solution
furthermore,
where GT:={(t,x)∈R2:x∈[g(t),h(t)],t∈(0,T]},C and T only depend on h0,α,‖u0‖C2([-h0,h0]).
and(u,g,h)is a solution to(1.1),then
Proof.The proof of Lemma 2.1 is identical to that of Lemma 5.7 in [7],so we omit the details here.
Remark 2.1.The triplein Lemma 2.1 is often called an upper solution of(1.1).A lower solution can be defined analogously by reversing all the inequalities.
In this section,we mainly determine the asymptotic behavior of the solution of(1.1).Similar to the references[2,3,8],we will give some sufficient conditions that imply blowup(∞)or vanishing(0).We first construct the energy functional as follows:
The following lemma gives the basic energy identity.
Lemma 3.1.Let u be the solution of the problem(1.1),then we have the relations
Integrating by parts,we get
Integrating(3.7),we obtain(3.2).Now the proof is completed.
Proof.In order to get the estimates ofL,we assumevis the solution of the following auxiliary problem:
It is well-known thatvexists for allt>0 and we can deduce from Lemma 2.1 thatu≥v≥0 andg(t)≤λ(t)≤-h0,h(t)≥σ(t)≥h0on(0,T*).By the same argument as in Lemma 3.1,denoting|v(t)|1=v(t,x)dx,we easily get
On the other hand,by the comparison principle,we havev ≤,wheresatisfies the following Cauchy problem
By theL1-L∞estimate for the equation,we have
Therefore,by(3.8),we have
Next we give the lower bound of the constantL.By using H¨older’s inequality,we deduce
Noticing thatg(t)≤λ(t)≤-h0,h(t)≥σ(t)≥h0on(0,T*)and(3.8),we have
By(3.9)and plugging the valuet=t0into(3.10),we have
The proof now is completed.
The following result indicates the conditions for blowup.
Lemma 3.3.Let u be the solution of the problem(1.1),then we have T*<∞whenever
Proof.Arguing by contradiction,we assumeT*=∞.The assumption(3.11)and Lemma 3.2 imply that
for allt≥t0sufficiently large.
Define the function
Then we have
and
Using identity(3.1),we have
Noticing that(3.12)holds fort≥t0sufficiently large,we have
By applying the Cauchy-Schwarz inequality,we obtain
On the other hand,(3.13)implies that
so we have limt∞I(t)=∞.Then we obtain
for some larget1≥t0+1(sincep>1).DefiningJ(t):=(t)fort≥t1,then we have
This implies thatJis concave,decreasing and positive fort≥t1,which is impossible.This contradiction shows thatT*<∞.The proof is completed.
As a consequence of Lemmas 3.1-3.3,we immediately have the following blowup result.
Theorem 3.1.Let u be the solution of the problem(1.1),if
then the solution will blow up in finite time.
Remark 3.1.In Theorem 3.1,we denote
it is easy to obtain
andH(β)0 when∞.Thus we conclude that large advection is not favorable for blowup.
In the following part,we give the long-time behavior of the global solutions of the problem(1.1)and we obtain the decay rate of the global solution.
Theorem 3.2.Let u be the solution of the problem(1.1).If u0is so small such that
then T*=∞.Moreover,h∞<∞,g∞>-∞and there exist real numbers C and γ>0depending on u0such that
Proof.We construct some suitable global upper solution of the problem(1.1).Motivated by[3,9],we define
whereα,γandϵto be fixed later.A direct calculation shows that
for allt≥0 andη(t)≤x≤ρ(t).Moreover,we haveρ′(t)=2h0αe-αt>0 and-µx(t,ρ(t))=2µϵρ-1(t)eBy the definition ofρ(t),we can derive that 2h0≤ρ(t)≤4h0for allt≥0.If we choose
we have
Now we assume(3.14)holds and takeϵ=2e‖u0‖L∞≤ϵ0,then we haveu0(x)≤(0,x)for-h0≤x ≤h0.By the comparison principle,we obtainη(t)≤g(t),h(t)≤ρ(t) andu(t,x)≤(t,x)forη(t)≤x≤ρ(t),t>0 as long asuexists.The proof is now complete.
Remark 3.2.Theorem 3.2 indicates that the double free boundaries converge to finite limits and the solutionudecays at a exponential rate astgoes to infinity provided the initial value is small.Moreover,we see that it is more difficult to obtain the solution in Theorem 3.2 provided the advection is larger.
Acknowledgement
This work is supported by Natural Science Foundation of China(No.11901238)and Natural Science Foundation of Shandong Province(No.ZR2019MA063).
Journal of Partial Differential Equations2023年4期