Persistence properties and blow-up phenomena for a generalized Camassa–Holm equation

In this paper, we investigate a generalized Camassa–Holm equation. Firstly, we establish the persistence properties of strong solutions for the equation in weighted spaces \(L^{p}_{\phi}=L^{p}(\mathbb{R},\phi ^{p}\,dx)\). Then we present some sufficient conditions of blow-up solutions assuming that the initial data satisfy certain conditions, which are more precise than those in the previous work.

In 2009, Novikov [26] used the perturbative symmetry approach to deduce a series of generalized Camassa–Holm equations, including both quadratic and cubic nonlinearities, which are integrable and possess an infinite hierarchy of quasi-local higher symmetries. They are of the following structure:

where F is a function of u and its derivatives with respect to x, and the subscript denotes partial derivative. Among them, the most celebrated example is the Camassa–Holm equation (also called the CH equation)

derived by Camassa and Holm [2] and Fokas and Fuchssteiner [11]. It describes the motion of shallow water waves and possesses a Lax pair, a bi-Hamiltonian structure, and infinitely many conserved integrals [2]. It can be solved by the inverse scattering method. One of the remarkable features of the CH equation is that it has the single-peakon solutions

and the multipeakon solutions

where \(p_{i}(t)\) and \(q_{i}(t)\) satisfy the Hamilton system [2]

with Hamiltonian \(H=\frac{1}{2}\sum_{i,j=1}^{N}p_{i}p_{j}e^{|q_{i}|}\). It is shown that those peaked solitons are orbitally stable in the energy space [9]. Another remarkable feature of the CH equation is the so-called wave-breaking phenomenon, that is, the wave profile remains bounded while its slope becomes unbounded in finite time [5–7]. Hence equation (2) has attracted lots of attention since it was born. The dynamic properties related to the equation can be found in [4, 8, 10, 12, 14–20, 23, 31, 33–38] and the references therein.

The other example is the Novikov equation

It is shown in [26] that equation (3) possesses soliton solutions, infinitely many conserved quantities, a Lax pair in matrix form, and a bi-Hamiltonian structure. The conserved quantities

and

play an important role in the study of the dynamic properties related to equation (3). More information about the Novikov equation can be found in Tiglay [27], Ni and Zhou [25], Wu and Yin [29, 30], Yan, Li, and Zhang [32], Mi and Mu [24] and the references therein.

In this paper, we are interested in the following equation:

for \(t>0\) and \(x\in \mathbb{R}\), and u stands for the unknown function on the line \(\mathbb{R}\). Problem (4) admits traveling wave solutions and possesses conserved laws [21]

Tu and Yin [28] established the local well-posedness for the Cauchy problem in the critical Besov spaces \(B^{\frac{1}{2}}_{2,1}\) relying on the Littlewood–Paley decomposition, transport equations theory, logarithmic inequalities, and Osgood’s lemma. The global existence of a strong solution and some blow-up results are also presented. It is shown in [21] that the solutions of problem (4) are velocity potentials of the classical Camassa–Holm equation and also are locally well posed in the other Besov spaces \(B^{s}_{p,r}\), \(s>\max \{\frac{1}{p},\frac{1}{2}\}\). To our best knowledge, the asymptotic behaviors for the Cauchy problem (4) have not been studied yet. In this paper, we first investigate the asymptotic behaviors of the strong solutions for problem (4) in weighted spaces \(L^{p}_{\phi}:=L^{P}(\mathbb{R},\phi ^{p}\,dx)\), extending the result in [22]. Then we present some blow-up results, provided that the initial data satisfy certain conditions, which are more precise than those in [28].

Notations

The space of all infinitely differentiable functions \(\phi (t,x)\) with compact support in \([0,+\infty )\times \mathbb{R}\) is denoted by \(C^{\infty}_{0}\). Let \(L^{p}=L^{p}(\mathbb{R})(1\leq p<+\infty )\) be the space of all measurable functions h such that \(\Vert h\Vert ^{P}_{L^{P}}=\int _{\mathbb{R}}|h(t,x)|^{p}\,dx<\infty \). We define \(L^{\infty}=L^{\infty}(\mathbb{R})\) with the standard norm \(\Vert h\Vert _{L^{\infty}}=\mathrm{inf}_{m(e)=0}\mathrm{sup}_{x\in R \setminus e}| h(t,x)|\). For any real number s, \(H^{s}=H^{s}(\mathbb{R})\) denotes the Sobolev space with the norm

where \(\hat{h}(t,\xi )=\int _{\mathbb{R}}e^{-ix\xi}h(t,x)\,dx\).

We denote by ∗ the convolution. Note that if \(G(x):=\frac{1}{2}e^{-|x|}\), \(x\in \mathbb{R}\), then \((1-\partial ^{2}_{x})^{-1}f=G\ast f\) for all \(f\in L^{2}(\mathbb{R})\), and \(G\ast (u-u_{xx})=u\). Using this identity, we rewrite problem (4) as follows:

for \(t>0\) and \(x\in \mathbb{R}\), which is equivalent to

Motivated by the recent work [22, 35, 36], the aim of this section is to establish the persistence properties for a generalized Camassa–Holm equation in the weighted \(L^{p}\) spaces. Let us first give some standard definitions.

Definition 2.1

An admissible weight function for problem (4) is a locally absolutely continuous function \(\phi :\mathbb{R}\rightarrow \mathbb{R}\) such that, for some \(A>0\) and almost all \(x\in \mathbb{R}\), \(|\phi '(x)|\leq A|\phi (x)|\), and that is v-moderate for some submultiplicative weight function v satisfying \(\inf_{\mathbb{R}}v>0\) and

Definition 2.2

In general, a weight function is simply a nonnegative function \(v: \mathbb{R}^{n}\rightarrow \mathbb{R}\), which is called submultiplicative if

Given a submultiplicative function v, a positive function ϕ is v-moderate if and only if

If ϕ is v-moderate for some submultiplicative function v, then we say that ϕ is moderate. This is usually used in the theory of time-frequency analysis [1]. Let us recall the most standard example with such weights. Let

Then we have the following two properties [22].

(i) For \(a,c,d\geq 0\) and \(0\leq b\leq 1\), such a weight is submultiplicative.

(ii) If \(a,c,d \in \mathbb{R}\) and \(0\leq b\leq 1\), then ϕ is moderate. More precisely, \(\phi _{a,b,c,d}\) is \(\phi _{\alpha ,\beta ,\gamma ,\delta}\)-moderate for \(|a|\leq \alpha \), \(|b|\leq \beta \), \(|c|\leq \gamma \), and \(|d|\leq \delta \).

The elementary properties of submultiplicative and moderate weights can be found in [22]. Let us collect our results on admissible weights.

Lemma 2.1

([22])

Let \(v: \mathbb{R}^{n}\rightarrow \mathbb{R}^{+}\) and \(C_{0}>0\). Then the following conditions are equivalent:

1. (1)

   \(\forall x,y:v(x+y)\leq C_{0}v(x)v(y)\);

2. (2)

   for all \(1\leq p,q,r\leq \infty \) and for any measurable functions \(f_{1}, f_{2}:\mathbb{R}^{n}\rightarrow C\), we have the weighted Young inequality

   $$\begin{aligned} \bigl\Vert (f_{1}\ast f_{2})v \bigr\Vert _{r}\leq C_{0} \Vert f_{1}v \Vert _{p} \Vert f_{2}v \Vert _{q},\quad 1+ \frac{1}{r}= \frac{1}{p}+\frac{1}{q}. \end{aligned}$$

Lemma 2.2

([22])

Let \(1\leq p\leq \infty \), and let v be a submultiplicative weight on \(\mathbb{R}^{n}\). The following two conditions are equivalent:

1. (1)

   ϕ is a v-moderate weight function (with constant \(C_{0}\));

2. (2)

   for all measurable functions \(f_{1}\) and \(f_{2}\), we have the weighted Young estimate

   $$\begin{aligned} \bigl\Vert (f_{1}\ast f_{2})\phi \bigr\Vert _{p}\leq C_{0} \Vert f_{1}v \Vert _{1} \Vert f_{2}\phi \Vert _{p}. \end{aligned}$$

Theorem 2.1

Let \(T>0\), \(s>\frac{5}{2}\), and \(2\leq p\leq \infty \). Assume that \(u\in C([0,T], H^{s}(\mathbb{R}))\) is a strong solution of problem (4) such that \(u(0,x)=u_{0}\) satisfies

where ϕ is an admissible weight function for problem (4). Then, for all \(t\in [0,T]\), we have the estimate

for some constant \(C>0\) depending only on v, ϕ (through the constants A, \(C_{0}\), \(\inf_{x\in \mathbb{R}}v\), and \(\int _{\mathbb{R}}\frac{v(x)}{e^{|x|}}\,dx<\infty \)), and

Proof

Assume that ϕ is v-moderate and satisfies the above conditions. From the assumption \(u\in C([0,T],H^{s})\), \(s>5/2\), we get

For any \(N\in Z^{+}\), let us consider the N-truncations of ϕ: \(f(x)=f_{N}(x)= \min \{\phi ,N\}\). Then \(f:\mathbb{R}\rightarrow \mathbb{R}\) is a locally absolutely continuous function such that

On the other hand, if \(C_{1}=\max \{C_{0},\alpha ^{-1}\}\), where \(\alpha =\inf_{x\in \mathbb{R}}v(x)>0\), then

In addition, as shown in [22], the N-truncations f of a v-moderate weight ϕ are uniformly v-moderate with respect to N. We begin to consider the case \(2\leq p< \infty \). Multiply the first equation of problem (6) by \(f|uf|^{p-2}(uf)\) and integrate to obtain

For the first term on the left-hand side of (9), we have

and the third term on the left-hand side of (9) reads

where we used the Hölder inequality, Lemmas 3.1 and 3.2, and (8). For the second term, we have

From (9) we obtain

Now we will give estimates on \(u_{x}f\). Differentiating the first equation of problem (6) with respect to x, we get

which multiplied by f results in the equation

Multiplying (15) by \(|u_{x}f|^{p-2}(u_{x}f)\) with \(p\in Z^{+}\) and integrating give the equation

Using as similar procedure, we obtain the estimates

and

where we used \(|\partial _{x}G(x)|<\frac{1}{2}e^{-|x|}\). Therefore from (16)–(19) it follows that

Next, we focus on estimates of \(u_{xx}f\). Differentiating (14) with respect to x and multiplying by f result in the equation

Multiply by \(|u_{xx}f|^{p-2}(u_{xx}f)\) with \(p\in Z^{+}\) and integrate to obtain the equation

Notice that the estimates

and

hold, where we used the equality \(\partial ^{2}_{x}G=G-1\).

For the third-order derivative term, we have

Therefore from (22)–(26) it follows that

Now, combining (13), (20), and (27), we deduce

Integrating (28) gives

Since \(f(x)=f_{N}(x)\rightarrow \phi (x)\) as \(N\rightarrow \infty \) for a.e. \(x\in \mathbb{R}\), recalling that \(u_{0}\phi \), \(u_{0x}\phi \), \(u_{0xx}\phi \in L^{p}\), we deduce

Finally, we will treat the case \(p=\infty \). We have \(u_{0}\), \(u_{0x}\), \(u_{0xx}\in L^{2}\cap L^{\infty}\) and \(f(x)=f_{N}(x)\in L^{\infty}\). So we obtain

for \(q\in [2,\infty )\), where the last factor on the right-hand side is independent of q. Since \(\| f\| _{L^{p}}\rightarrow \| f\| _{L^{ \infty}}\) as \(p\rightarrow \infty \) for any \(f\in L^{2}\cap L^{\infty}\), we get

where the last factor on the right-hand side is independent of N. Now taking the limit as \(N\rightarrow \infty \) implies that estimate (31) remains valid for \(p=\infty \). □

Remark 1

(1) Let \(\phi =\phi _{0,0,c,0}\) with \(c>0\), and let \(p=\infty \). Then Theorem 2.1 states that the condition

implies the uniform algebraic decay in \([0,T]\):

It is shown that the algebraic decay rates of a strong solution to problem (4) are obtained.

(2) Let \(\phi =\phi _{a,1,0,0}\) if \(x\geq 0\) and \(\phi (x)=1\) if \(x\leq 0\) with \(0\leq a<1\). It is easy to see that such a weight satisfies the admissibility conditions of Definition 2.1. Moreover, let \(p=\infty \) in Theorem 2.1. Then problem (4) preserves the pointwise decay \(O(e^{-ax})\) as \(x\rightarrow +\infty \) for each \(t>0\). Similarly, we have persistence of the decay \(O(e^{-ax})\) as \(x\rightarrow -\infty \).

Clearly, the limit case \(\phi =\phi _{1,1,c,d}\) is not covered in Theorem 2.1. Furthermore, in the following theorem, we may choose the weight \(\phi =\phi _{1,1,c,d}\) with \(c<0\), \(d\in \mathbb{R}\), and \(\frac{1}{|c|}< p\leq \infty \). More generally, when \((1+|\cdot |)^{c}\log (e+|\cdot |)^{d}\in L^{p}(\mathbb{R})\), Theorem 2.2 covers the case of fast growing weights, which means that when a v-moderate weight ϕ does not satisfy condition (8), we may establish a variant of Theorem 2.1, putting instead of assumption (8), the following weaker condition:

where \(2\leq p\leq \infty \).

Theorem 2.2

Let \(2\leq p\leq \infty \), let ϕ be a v-moderate weight function as in Definition 2.1satisfying condition (33), and let the initial data \(u_{0}=u(0,x)\) satisfy

Then the strong solution u of the Cauchy problem for (4), emanating from \(u_{0}\), satisfy

and

Remark 2

Let \(\phi =\phi _{1,1,0,0}(x)=e^{|x|}\) and \(p=\infty \) in Theorem 2.2. If \(|u_{0}(x)|\), \(|u_{0,x}(x)|\), and \(|u_{0,xx}|\) are bounded by \(Ce^{-|x|}\), then the strong solution satisfies

uniformly in \([0,T]\).

Proof

The assumption that ϕ is a v-moderate weight function implies

which, combined with \(\inf_{R}v>0\), gives

that is, \(\phi ^{\frac{1}{2}}\) is a \(v^{\frac{1}{2}}\)-moderate weight function. The inequality \(|\phi '(x)|\leq A|\phi (x)|\) reads

By condition (33), \(ve^{-|x|}\in L^{p}\). So the Hölder inequality yields

Thus Theorem 2.1 with \(p=2\) applied to the weight \(\phi ^{\frac{1}{2}}\) results in

From Lemma 2.2 and \(f(x)=f_{N}(x)=\min \{\phi (x),N\}\), applying (33), we have

Similarly, we have the estimates

and

Here the constants on the right-hand side of (35)–(37) are independent of N. By using the procedure as in the proof of Theorem 2.1, we readily get

and

Substituting (35), (36), and (37) into (38), (39), and (40), respectively, and summing up them, we have

From Gronwall’s inequality it follows that

We obtain desired result by letting \(N\rightarrow \infty \) in the case \(2\leq p<\infty \). The constants throughout the proof are independent of p. So for \(p=\infty \), we can obtain the result from that established for the finite exponents q by letting \(q\rightarrow \infty \). The rest of the proof is fully similar to that of Theorem 2.1. □

3.1 Several lemmas

In this section, we study the sufficient conditions of blow-up solutions for problem (4) by using some classical methods. Firstly, we need several lemmas.

Lemma 3.1

([3])

Let \(f\in C^{1}(\mathbb{R})\), \(a>0\), \(b>0\), and \(f(0)>\sqrt{\frac{b}{a}}\). If \(f'(t)\geq af^{2}(t)-b\), then

Lemma 3.2

([13])

Let \(u_{0}\in H^{s}\), \(s\geq 5/2\). Then the corresponding solution u has the constant energy integral

Lemma 3.3

([13])

Let \(u_{0}\in H^{s}\), \(s\geq 5/2\). Let T be the lifespan of the solution to problem (4). Then the corresponding solution blows up in finite time if and only if

Remark 3

From Lemma 3.2 we see that \(u(t,x)\) is bounded. This implies that the solution to problem (4) blows up if and only if

3.2 Blow-up phenomenon

Theorem 3.1

Let \(u_{0}\in H^{s}(\mathbb{R})\) for \(s>\frac{3}{2}\). Let \(u(t,x)\) be the corresponding solution of with the initial datum \(u_{0}\). Suppose that the slope of \(u'_{0}\) satisfies

where \(K^{2}=\frac{(24+3\sqrt{2})^{2}}{16}\Vert u'_{0}\Vert ^{4}_{H^{1}}\) and \(K^{2}_{1}=\frac{1}{4\| u'_{0}\| ^{2}_{H^{1}}}\). Then there exists the lifespan \(T<\infty \) such that the corresponding solution \(u(t,x)\) blows up in finite time T with

Proof

Define \(g(t)=u_{x}(t,x)\) and \(h(t)=\int _{\mathbb{R}}g^{3}_{x}\,dx\). Then it follows that

where \(Q=\partial _{x}(1-\partial ^{2}_{x})^{-1}(u^{2}_{x}+\frac{1}{2}u^{2}_{xx})\).

Differentiating equation (46) with respect to x yields

Multiplying by \(3g^{2}_{x}\) both sides of (47) and integrating with respect to x over \(\mathbb{R}\), we have

Using Hölder’s and Yong’s inequalities, (5), and (48), we get

and

Combining inequalities (49)–(51), we obtain

Choosing \(\epsilon =\frac{2}{24+3\sqrt{3}}\) yields

Therefore, combining (48) and (52), we get

where \(K^{2}=\frac{(24+3\sqrt{2})^{2}}{16}\| u'_{0}\| ^{4}_{H^{1}}\). Using Hölder’s inequality, we get

Combining (54) and (55), we have

where \(K^{2}_{1}=\frac{1}{4\| u'_{0}\| ^{2}_{H^{1}}}\).

From the assumption of the theorem we have that \(h(0)>\frac{K}{K_{1}}\), and the continuity argument ensures that \(h(t)>h(0)\). Lemma 3.1 (with \(a=K^{2}_{1}\) and \(b=K^{2}\)) implies that \(h(t)\rightarrow +\infty \) as \(t\rightarrow T=\frac{1}{2K_{1}K}\log \frac{K_{1}h(0)+K}{K_{1}h(0)-K}\).

On the other hand, using the fact that

Remark 3 implies the statement of Theorem 3.1.

The characteristics \(q(t,x)\) related to problem (4) is governed by

Applying the classical results in the theory of ordinary differential equations, we can obtain that the characteristics \(q(t,x)\in C^{1}([0,T)\times \mathbb{R})\) with \(q_{x}(t,x)=e^{\int ^{t}_{0}-u_{xx}(\tau ,q(\tau ,x))\,d\tau}>0\) for all \((t,x)\in [0,T)\times \mathbb{R}\). Furthermore, it is shown in [28] that the potential \(y=u-u_{xx}\) satisfies

Therefore we obtain the second blow-up result. □

Theorem 3.2

Let \(u_{0}\in H^{s}(\mathbb{R})\), \(s>\frac{5}{2}\). Suppose that there is a point \(x_{2}\in \mathbb{R}\) such that

Then the blow-up occurs in finite time

Proof

We track the dynamics of \(P(t)= (u_{x}-\frac{\sqrt{2}}{2}u_{xx} )(t,q(t,x_{2}))\) and \(Q(t)= (u_{x}+\frac{\sqrt{2}}{2}u_{xx} )(t, q(t,x_{2}))\) along the characteristics

and

From (59) we see that the right-hand side of (60) is positive and the right-hand side of (61) is negative initially. Hence P increases, and Q decreases. Then we obtain

Letting \(h(t)=\sqrt{-PQ(t)}\) and using the estimate \(\frac{Q-P}{2}\geq h(t)\), we have

In view of Lemma 3.1, we obtain that \(h\rightarrow +\infty \) as \(t\rightarrow T_{0}\) with

Observe that \(h(t)=\sqrt{\frac{1}{2}u^{2}_{xx}-u^{2}_{x}}<| \frac{\sqrt{2}}{2}u_{xx}(t,q(t,x_{2})) | \). Therefore \(h\rightarrow +\infty \) as \(t\rightarrow T_{0}\) implies that \(| u_{xx}(t,q(t,x_{2}))| \rightarrow +\infty \) as \(t\rightarrow T_{0}\).

The proof of Theorem 3.2 is completed. □

Theorem 3.3

Let \(u_{0}\in H^{s}(\mathbb{R})\) for \(s>\frac{5}{2}\). Suppose that there exists \(x_{3}\in \mathbb{R}\) such that \(u_{0xx}(x_{3})>\Vert u'_{0}\Vert _{H^{1}}\). Then the wave breaking occurs in finite time

Proof

Now we prove the wave-breaking phenomenon along the characteristics \(q(t,x_{3})\). It follows from (6) that

and

Since \((1-\partial ^{2}_{x})^{-1} (u^{2}_{x}+\frac{1}{2}u^{2}_{xx} )\geq \frac{1}{2}u^{2}_{x}\), we get

Setting \(M(t)=u_{xx}(t,q(t,x_{3}))\) and using Young’s inequality, Lemmas 3.1 and 3.2, and (69), we get

where \(K_{2}=\frac{1}{2}\| u'_{0}\| ^{2}_{H^{1}}\).

Since by the assumption of Theorem 3.2, \(u_{0xx}(x_{3})>\| u'_{0}\| _{H^{1}}\), solving (70) results in

where \(T^{\ast}=\frac{1}{\| u'_{0}\| _{H^{1}}}\log ( \frac{u_{0xx}(x_{3})+\| u'_{0}\| _{H^{1}}}{u_{0xx}(x_{3})-\| u'_{0}\| _{H^{1}}} )\). □

Not applicable.

This work is funded by the Guizhou Province Science and Technology Basic Project (Grant No. QianKeHe Basic [2020]1Y011).

Authors and Affiliations

1. Department of Mathematics, Zunyi Normal University, 563006, Zunyi, China

   Ying Wang & Yunxi Guo

Contributions

Ying Wang wrote the manuscript text and Yunxi Guo revised the manuscript. Both authors reviewed the manuscript.

Corresponding author

Correspondence to Yunxi Guo.

Ethics approval and consent to participate

This study does not involve human experiments and animal studies.

Competing interests

The authors declare no competing interests.

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