1 Introduction

In this paper, we consider the following weakly damped wave equation:

$$\begin{aligned} \textstyle\begin{cases} u_{tt}+u_{t}-\Delta u-\lambda u+\varphi (u)=0, & (x,t)\in \varOmega \times \mathbb{R}^{+}, \\ u=0, &(x,t)\in \partial \varOmega \times \mathbb{R}^{+}, \\ u(x,0)=u_{0}(x),u_{t}(x,0)=u_{1}(x) & x\in \varOmega , \end{cases}\displaystyle \end{aligned}$$
(1.1)

where \(\varOmega \subset R^{3}\) is a bounded domain with smooth boundary ∂Ω. Let

$$\begin{aligned} 0< \lambda _{1}< \lambda _{2}\leq \cdots \leq \lambda _{m}< \lambda _{m+1}< \cdots \end{aligned}$$

be the sequence of eigenvalues of −Δ on \(H_{0}^{1}(\varOmega )\), and let \(e_{j}\) be the eigenfunctions corresponding to \(\lambda _{j}\), \(j=1,2,\ldots \) . Here we assume that \(\lambda \in (\lambda _{m}, \lambda _{m+1})\). We also impose the following assumptions on the nonlinear term φ:

\((A)\) :

\(\varphi \in C(R)\) is of the form

$$ \varphi (s)=s^{3}-\beta \vert s \vert ^{\gamma }s, $$

where β is a parameter, and \(0<\gamma <2\). The number 3 is called the critical exponent, since the nonlinearity f is not compact in this case.

The existence of the global attractor (see Definition 2.2) for wave equations like (1.1) has been studied extensively by many authors; we refer to [1, 2, 11, 14] and the references therein for more detail.

We now want to examine the attractor itself in more detail. In concise, we study the properties of the global attractor and obtain the existence of multiple equilibrium points (see Def. 2.6) in the global attractor in \(H^{1}_{0}(\varOmega )\times L^{2}(\varOmega )\).

It is well known that if a system or a semigroup \(\{S(t)\} _{t\geq 0}\) has a global attractor \(\mathcal{A}\) in a Banach space X and has a Lyapunov function F (see Def. 2.5) on some neighborhood of \(\mathcal{A}\), then

$$\begin{aligned} \mathcal{A}=W^{u}(\mathcal{E}), \end{aligned}$$

where \(\mathcal{E}\) is the set of all fixed points, and \(W^{u}( \mathcal{E})\) is the unstable manifold (see Def. 2.8) of \(\mathcal{E}\). Furthermore, if \(\mathcal{E}\) is discrete, then

$$\begin{aligned} \mathcal{A}=W^{u}(\mathcal{E})=\bigcup_{z\in \mathcal{E}} W^{u}(z), \end{aligned}$$

(see [12, 14] etc.). On the other hand, all complete bounded orbits lie in the global attractor \(\mathcal{A}\) (see[12] etc.), that is,

$$\begin{aligned} \bigl\{ \theta (t):\theta (t) \text{ is a complete bounded orbit of } \bigl\{ S(t) \bigr\} _{t\geq 0}\bigr\} \subset \mathcal{A}. \end{aligned}$$

We also note that the global attractor is connected if the phase space is connected (see [12, 14] etc). As the phase spaces we consider are usually Hilbert or Banach spaces, the global attractor is connected.

In this case, each complete bounded orbit \(\theta (t)\) is always connected to some pair of fixed points of a semigroup \(\{S(t)\}_{t \geq 0}\), and \(\theta (t)\) is contained in the unstable manifold from the one fixed point (see Def. 2.6) and the stable manifold (see Def. 2.7) from the other fixed point. From this point of view, if the number of fixed points in \(\mathcal{A}\) is large, then the structure of such an attractor can be completely specified by a list of fixed points that are joined to each other. Thus, it is meaningful for us to investigate the multiplicity of equilibrium points in the global attractor \(\mathcal{A}\).

To the best of our knowledge, there are few related results. Fortunately, recently, the authors in [18] and [16] established the criterions to show the existence of the multiplicity of equilibrium points under some proper conditions.

In detail, if the semigroup \(\{S(t)\}_{t\geq 0}\) is odd and the Lyapunov function F is even, and if the origin is a strictly local minimum point of F, then the authors in [18] have proved the existence of the multiple equilibrium points in the global attractors for the symmetric dynamical systems by estimating the lower bound of \(Z_{2}\) index of two disjoint subsets of the global attractor for which one subset is located in the area where the Lyapunov function F is positive and the other subset is located in the area where the Lyapunov function F is negative. As applications, the authors have considered the reaction–diffusion equations [18], wave equations [8, 9], and p-Laplacian equation [15] and proved that the corresponding semigroups \(\{S(t)\}_{t\geq 0}\) possess at least 2n pairs of different fixed points in the global attractor \(\mathcal{A}\).

On the other hand, if the origin is no longer a strictly local minimum point but a saddle point of F, then we cannot estimate the lower bound of \(Z_{2}\) index of the global attractor by the method or technique in [18]. Fortunately, in [16], by proving a new lemma, which is analogous to the intersection lemma in [13], we can still prove the existence of multiple fixed points in a global attractor for some symmetric semigroups with a Lyapunov function F. To be precise, in [16] the authors have mainly obtained the following results.

Theorem 1.1

Let X be a Banach space, and let \(\{S(t)\}_{t\geq 0}\) be a continuous semigroup on X. Assume that \(\{S(t)\}_{t\geq 0}\) satisfies the following conditions:

\((A'_{1})\) :

\(S(t):X\rightarrow X\) is odd for each \(t\geq 0\),

\((A'_{2})\) :

\(\{S(t)\}_{t\geq 0}\) possesses a global attractor \(\mathcal{A}\) in X,

\((A'_{3})\) :

\(\{S(t)\}_{t\geq 0}\) has a \(C^{0}\) even Lyapunov function F on X,

\((A'_{4})\) :

There exist two closed subspaces \(X^{+}\) and \(X^{-}\) of X satisfying

(\(A'_{4}\)-i):

\(\operatorname{codim} X^{+}\leq \dim X^{-}<\infty \) and \(X=X^{+}+X^{-}\), and

(\(A'_{4}\)-ii):

there exist two positive constants α and ϱ such that

$$\begin{aligned} F|_{X^{+}\cap \partial B(0,\delta )}\geq \alpha , \end{aligned}$$

where \(B(0,\varrho )\) is a ball of radius ϱ in X with center at the origin,

(\(A'_{4}\)-\(iii\)):

there exist two positive constants R and \(0<\rho <R\) such that

$$\begin{aligned} F|_{X^{-}\cap \partial B(0,R)}< \inf_{v\in \partial B(0,\rho )}F(v)< F(0)=0. \end{aligned}$$

Then we have:

  1. (i)
    $$\begin{aligned} \gamma (\mathcal{A}\cap F^{-1}\bigl((-\infty ,0]) \bigr)\geq \dim X ^{-}, \end{aligned}$$

    where \(\delta = \inf_{v\in \partial B(0,\rho )}F(v)<0\) and \(F ^{-1}((-\infty ,\delta ])=\{u\in X:F(u)\leq \delta \}\),

  2. (ii)
    $$\begin{aligned} \gamma \bigl(\mathcal{A}\cap F^{-1}\bigl([\alpha ,\infty \bigr)\bigr) )\geq \dim X^{-}-\operatorname{codim} X^{+}, \end{aligned}$$

    where \(F^{-1}([\alpha ,\infty ))=\{u\in X:\alpha \leq F(u)<\infty \}\).

Theorem 1.2

Let \(\{S(t)\}_{t\geq 0}\) be a continuous semigroup on X. Under the assumptions of Theorem 1.1, the semigroup \(\{S(t)\}_{t\geq 0}\) possesses at least \(\dim X^{-}-\operatorname{codim} X^{+}\) pairs of different fixed points in \(\mathcal{A}\cap F^{-1} ((0,\infty ) )\).

As an application of Theorems 1.1 and 1.2, the authors have considered the reaction–diffusion equations in [16] and the p-Laplacian equation in [7].

The current paper is mostly related to [9] and motivated by [16]. In [9] the authors have proved the existences of multiple equilibrium points in the global attractor of (1.1) with \(\lambda =0\). The essential difference between this paper and [9] is that the origin is not a local minimum point but a saddle point of the corresponding Lyapunov function. Also, compared with the reaction–diffusion equations in [16], the phase space of the wave equation is the product space \(H^{1}_{0}(\varOmega )\times L ^{2}(\varOmega )\); nevertheless, to apply Theorem 1.1, one key point is to decompose the phrase space, and we present a new strategy to decompose the product space (see the proof of Theorem 3.3 in detail).

The rest of the paper is organized as follows. In the next section, for the convenience of the reader, we provide some preliminaries. In Sect. 3, by applying Theorems 1.1 and 1.2, we consider the existence of multiple stationary solutions for some symmetric wave equation with weak damping.

Throughout this paper, X is a Banach space endowed with norm \(\|\cdot \|_{X}\), and C is any positive constant which may be different from line to line and even in the same line.

2 Preliminaries

We first give some basic definitions about semigroups and global attractors, which can be found in [1, 4, 10, 12, 14] and references therein.

Definition 2.1

Let \(\{S(t)\}_{t\geq 0}\) be a family of operators on X. We say that \(\{S(t)\}_{t\geq 0}\) is a \(C^{0}\) semigroup on X if \(\{S(t)\}_{t \geq 0}\) satisfies the following conditions:

  1. (i)

    \(S(0) = \mathit{Id}\) (the identity),

  2. (ii)

    \(S(t)S(s) = S(t + s)\) for all \(t,s\geq 0\),

  3. (iii)

    \(S(t_{n})x_{n} \rightarrow S(t)x\) if \(t_{n} \rightarrow t\) and \(x_{n} \rightarrow x\) in X.

Definition 2.2

Let \(\{S(t)\}_{t\geq 0}\) be a continuous semigroup on X. A subset \(\mathcal{A}\) in X is called a global attractor if

  1. (1)

    \(\mathcal{A}\) is invariant, that is, \(S(t)\mathcal{A}= \mathcal{A}\) for all \(t\geq 0\),

  2. (2)

    \(\mathcal{A}\) is compact in X,

  3. (3)

    \(\mathcal{A}\) attracts \(S(t)B\) as \(t\rightarrow \infty \) for each bounded subset B in X.

Now we restate the results (see [1, 11, 14] etc.) about the well-posedness of the solutions and the existence of the global attractor for (1.1).

Theorem 2.3

Under assumption \((A)\), for any \(T>0\) and \((u_{0},u_{1})\in H^{1}_{0}( \varOmega )\times L^{2}(\varOmega )\), there exists a unique solution of (1.1) such that

$$ (u,u_{t})\in C \bigl([0,T];H^{1}_{0}(\varOmega ) \times L^{2}(\varOmega )\bigr). $$

We define the mappings

$$\begin{aligned} S(t):(u_{0},u_{1})\rightarrow \bigl( u(t),u_{t}(t)\bigr) \end{aligned}$$
(2.1)

for all \(t\in R\). By Theorem 2.3 it is easy to see that \(\{S(t)\}_{t\geq 0}\) is a \(C_{0}\)-semigroup in the energy phase space \(H^{1}_{0}(\varOmega )\times L^{2}(\varOmega )\).

Theorem 2.4

Under assumption \((A)\), for any fixed β, problem (1.1) has a global attractor \(\mathcal{A_{\beta }}\) in \(H^{1}_{0}(\varOmega ) \times L^{2}(\varOmega )\).

Next, we briefly recall the notions of a Lyapunov function, stable manifolds, unstable manifolds, and the \(Z_{2}\) index; see [3, 6, 12,13,14] and references therein for more detail.

Definition 2.5

A Lyapunov function for \(S(t)\) on a positively invariant set \(X\subset H\) is a continuous function \(\varPhi :X\rightarrow \mathbb{R}\) such that

  1. (i)

    for each \(u_{0}\in X\), the function \(t\mapsto \varPhi (S(t)u_{0})\) is nonincreasing, and

  2. (ii)

    if \(\varPhi (S(\tau )u)=\varPhi (u)\) for some \(\tau >0\), then u is a fixed point of \(S(t)\).

Definition 2.6

A fixed point (or a stationary point, or an equilibrium point) is a point \(u_{0}\in H\) such that

$$\begin{aligned} S(t)u_{0}=u_{0} \quad \forall t\geq 0. \end{aligned}$$

If z is a fixed point, and H is the phase space, then we have the following definitions.

Definition 2.7

The stable manifold of z is the set

$$\begin{aligned} W^{s}(z)=\bigl\{ u_{0}\in H: S(t)u_{0} \text{ is defined for all } t, S(t)u_{0}\rightarrow z \text{ as } t\rightarrow \infty .\bigr\} \end{aligned}$$

Definition 2.8

The unstable manifold of z is the set

$$\begin{aligned} W^{u}(z)=\bigl\{ u_{0}\in H: S(t)u_{0} \text{ is defined for all } t, S(-t)u_{0}\rightarrow z \text{ as } t\rightarrow \infty .\bigr\} \end{aligned}$$

Denote the class of closed symmetric subsets of X by

$$\begin{aligned} \mathbb{A}=\{A\subset X: A \text{ is closed, } A=-A\}. \end{aligned}$$

Definition 2.9

Let \(A\in \mathbb{A}\), \(A\neq \emptyset \). The Krasnoselskii genus or \(Z_{2}\) index \(\gamma (A)\) of A is defined by

$$ \gamma (A)= \textstyle\begin{cases} \inf \{m:\exists h\in C^{0}(A, \mathbb{R}^{m}\backslash \{0\}), h(-u)=-h(u) \} \\ \infty , \quad \text{if } \{m:\exists h\in C^{0}(A, \mathbb{R}^{m}\backslash \{0\}), h(-u)=-h(u)\}=\emptyset ,\\ \hphantom{\infty , \quad\ } \text{in particular, if } 0 \in A, \end{cases} $$

and \(\gamma (\emptyset )=0\).

3 Main results

In this section, we consider the property of the global attractor \(\mathcal{A}_{\beta }\) of (1.1) and obtain that there are at least n pairs of different fixed points in the global attractor \(\mathcal{A}_{\beta }\). We first give two lemmas. Their proofs are similar to those in [9], and we omit them.

Lemma 3.1

For any fixed β, the semigroup \(\{S(t)\}_{t\geq 0}\) associated with the solutions of (1.1) is odd, and the global attractor \(\mathcal{A}_{\beta }\) obtained in Theorem 2.4 is symmetric.

Define the energy function

$$\begin{aligned} F(\phi )=F(u,u_{t})= \int _{\varOmega } \biggl\{ \frac{1}{2}\bigl( \vert \nabla u \vert ^{2}+ \vert u _{t} \vert ^{2}\bigr)- \frac{\lambda }{2} \vert u \vert ^{2}+\varPhi (u) \biggr\} \,dx, \end{aligned}$$
(3.1)

where \(\phi =(u,u_{t})\), and \(\varPhi (u)=\int _{0}^{u} \varphi (s) \,ds\) is the primitive function of \(\varphi (u)\).

Hereafter, we denote \(v=u_{t}\) and \(v_{0}=u_{t}(0)=u_{1}\).

Lemma 3.2

The function \(F(\phi )\) defined by (3.1) is an even Lyapunov function on \(H_{0}^{1}(\varOmega )\times L^{2}(\varOmega )\) for the semigroup \(\{S(t)\}_{t\geq 0}\).

Theorem 3.3

Suppose assumption \((A)\) holds, let \(\mathcal{A}_{\beta }\) be the global attractor of (1.1) for any fixed β, and let F be the Lyapunov function on \(X=H_{0}^{1}(\varOmega )\times L^{2}(\varOmega )\) for the semigroup \(\{S(t)\}_{t\geq 0}\) defined by (3.1). Then for any natural number n, there exists β large enough, and there exist closed subspaces \(X^{+}\) and \(X^{-}\) of X such that:

  1. (i)

    \(X=X^{+}+X^{-}\),

  2. (ii)

    \(\dim X^{-}-\operatorname{codim} X^{+}\geq n\),

  3. (iii)

    there exist \(\alpha >0\) and \(\delta >0\) such that \(F|_{X^{+}\cap \partial B(0,\delta )}\geq \alpha \),

  4. (iv)

    there exist R and \(0<\rho <R\) such that

    $$\begin{aligned} F|_{X^{-}\cap \partial B(0,R)}< \inf_{\phi \in \partial B(0,\rho )}F( \phi )< F(0)=0. \end{aligned}$$

Proof

Let \(Y=H^{1}_{0}(\varOmega )\) and \(Z=L^{2}(\varOmega )\). Denote by \(Y^{+}\) the closed subspace of Y spanned by \(e_{k}\), \(k=m+j\), \(j=1,2,\ldots \) , that is,

$$\begin{aligned} Y^{+}=\overline{\operatorname{span}\{e_{k}: k=m+j, j=1,2, \ldots \}}, \end{aligned}$$

where the closure is taken in Y. For any natural number n, denote

$$\begin{aligned} Y^{-}=\overline{\operatorname{span}\{e_{k}: k=1,2,\ldots ,m+n\}}. \end{aligned}$$

Set \(X^{-}=Y^{-}\times \{0\}\) and \(X^{+}=Y^{+}\times Z\). Then we easily obtain

$$ X=X^{+}+X^{-} $$

and

$$ \dim X^{-}-\operatorname{codim} X^{+}= n. $$

In the following, we prove (iii). For any \(\phi \in X^{+}\), we have

$$\begin{aligned} \Vert \nabla u \Vert ^{2}_{L^{2}(\varOmega )}\geq \lambda _{m+1} \Vert u \Vert ^{2}_{L^{2}( \varOmega )}. \end{aligned}$$

By the Sobolev embeddings \(H_{0}^{1}(\varOmega )\hookrightarrow L^{4}( \varOmega )\) and \(H_{0}^{1}(\varOmega )\hookrightarrow L^{\gamma +2}(\varOmega )\) we have

$$\begin{aligned} F(\phi )&= \int _{\varOmega }\biggl\{ \frac{1}{2}\bigl( \vert \nabla u \vert ^{2}+ \vert v \vert ^{2}\bigr)-\frac{ \lambda }{2} \vert u \vert ^{2}+Cu^{4}-\frac{\beta }{\gamma +2} \vert u \vert ^{\gamma +2}\biggr\} \,dx \\ &\geq \frac{1}{2} \Vert \nabla u \Vert _{L^{2}(\varOmega )}^{2}+ \frac{1}{2} \Vert v \Vert ^{2}_{L^{2}(\varOmega )}- \frac{\lambda }{2} \Vert u \Vert _{L^{2}(\varOmega )}^{2}+ C \Vert u \Vert ^{4}_{L^{4}(\varOmega )}-\frac{\beta }{\gamma +2} \Vert u \Vert ^{\gamma +2} _{L^{\gamma +2}(\varOmega )} \\ &\geq \biggl(\frac{1}{2}-\frac{\lambda }{2\lambda _{m+1}}\biggr) \Vert \nabla u \Vert _{L ^{2}(\varOmega )}^{2}+\frac{1}{2} \Vert v \Vert ^{2}_{L^{2}(\varOmega )} \\ &\quad {}+ C \Vert u \Vert ^{4} _{L^{4}(\varOmega )}-\frac{\beta }{\gamma +2}C \Vert \nabla u \Vert ^{\gamma +2} _{L^{2}}(\varOmega ), \end{aligned}$$
(3.2)

which implies that, for fixed β properly large, there exists a constant \(\delta >0\) such that, for any \(\phi \in X^{+}\cap \partial B(0,\delta )\),

$$ F|_{X^{+}\cap \partial B(0,\delta )}\geq \alpha , $$

where α is a fixed positive constant.

Finally, we prove (iv). For \(\phi _{1}=(e_{1},u_{t})\), we have

$$\begin{aligned} F(\varepsilon \phi _{1}) &= \int _{\varOmega }\biggl\{ \frac{1}{2}\varepsilon ^{2} \bigl( \vert \nabla e_{1} \vert ^{2}+ \vert u_{t} \vert ^{2}\bigr)-\frac{\lambda }{2} \vert \varepsilon e_{1} \vert ^{2}+ \varPhi (\varepsilon e_{1})\biggr\} \,dx \\ &= \int _{\varOmega }\biggl\{ \frac{1}{2}\varepsilon ^{2} \bigl( \vert \nabla e_{1} \vert ^{2}+ \vert u _{t} \vert ^{2}\bigr)-\frac{\lambda }{2} \vert \varepsilon e_{1} \vert ^{2}+C \varepsilon ^{4} \vert e_{1} \vert ^{4}-\frac{\beta }{\gamma +2}\varepsilon ^{\gamma +2} \vert e_{1} \vert ^{ \gamma +2}\biggr\} \,dx \\ &= \int _{\varOmega }\biggl\{ \frac{1}{2}\varepsilon ^{2} \vert u_{t} \vert ^{2}+\frac{ \lambda _{1}-\lambda }{2} \vert \varepsilon e_{1} \vert ^{2}+C \varepsilon ^{4} \vert e _{1} \vert ^{4}-\frac{\beta }{\gamma +2}\varepsilon ^{\gamma +2} \vert e_{1} \vert ^{ \gamma +2}\biggr\} \,dx. \end{aligned}$$
(3.3)

For any \(\phi \in X_{1}=\{u\in X|\|\nabla u\|_{L^{2}(\varOmega )}+\|u _{t}\|_{L^{2}(\varOmega )}=1\}\), by the Sobolev embedding \(H^{1}_{0}( \varOmega )\hookrightarrow L^{6}(\varOmega )\hookrightarrow L^{4}(\varOmega ) \hookrightarrow L^{\gamma +2}(\varOmega )\hookrightarrow L^{2}(\varOmega )\) we deduce that there exist positive constants \(\sigma _{1}\) and \(\sigma _{2}\) such that

$$\begin{aligned} \sup_{\phi \in X_{1}} \Vert u \Vert _{L^{2}(\varOmega )}^{2}= \sigma _{1},\qquad \sup_{\phi \in X_{1}} \Vert u \Vert _{L^{\gamma +2}(\varOmega )}^{\gamma +2}=( \gamma +2)\sigma _{2}. \end{aligned}$$

Hence we get

$$\begin{aligned} F(s\phi )&= \int _{\varOmega } \biggl\{ \frac{1}{2}s^{2}+Cs^{4} \vert u \vert ^{4}-\frac{ \lambda }{2} \vert su \vert ^{2}-\frac{\beta }{\gamma +2}s^{\gamma +2} \vert u \vert ^{\gamma +2} \biggr\} \,dx \\ &\geq -\frac{\lambda }{2}\sigma _{1}s^{2}-\sigma _{2}\beta s^{r}\rightarrow 0 \quad \text{as } s\rightarrow 0. \end{aligned}$$
(3.4)

Combining (3.3) with (3.4), we infer that there exists \(\rho \in (0,1)\) such that

$$\begin{aligned} -\infty < \inf_{\phi \in \partial B(0,\rho )}F(\phi )< 0 \end{aligned}$$

for properly large β. Then, for any \(\phi \in X_{2}:=\{u\in X ^{-}:\|u\|_{H_{0}^{1}(\varOmega )}+\|u_{t}\|_{L^{2}(\varOmega )}=\|u\|_{H _{0}^{1}(\varOmega )}=1\}\), there exists a constant \(\theta >0\) such that

$$\begin{aligned} \inf_{\phi \in X_{2}} \Vert u \Vert _{L^{\gamma +2}(\varOmega )}^{\gamma +2}=( \gamma +2)\theta . \end{aligned}$$
(3.5)

Therefore it follows from (3.5) that, for any \(\phi \in X_{2}\) and \(\mu \in \mathbb{R}\),

$$\begin{aligned} F(\mu \phi )&= \int _{\varOmega } \biggl\{ \frac{1}{2}\mu ^{2}\bigl( \vert \nabla u \vert ^{2}+ \vert u _{t} \vert ^{2}\bigr)+C\mu ^{4} \vert u \vert ^{4} - \frac{\lambda }{2} \vert \mu u \vert ^{2}-\frac{ \beta }{\gamma +2}\mu ^{\gamma +2} \vert u \vert ^{\gamma +2} \biggr\} \,dx \\ & \leq \frac{1}{2}\mu ^{2}+C\mu ^{4}- \frac{\lambda }{2\lambda _{1}}\mu ^{2}-\beta \mu ^{\gamma +2}\theta . \end{aligned}$$
(3.6)

We choose R such that \(R^{\gamma +2}\theta >\rho ^{\gamma +2}\sigma _{2}\). Then for properly large β, we get

$$\begin{aligned} F|_{X^{-}\cap \partial B(0,R)}< \inf_{\phi \in \partial B(0,\rho )}F( \phi )< F(0)=0. \end{aligned}$$

 □

From Theorems 1.1 and 1.2, Lemmas 3.1 and 3.2, and Theorem 3.3, we obtain the following theorem and corollary.

Theorem 3.4

Suppose assumption \((A)\) holds. Let \(\mathcal{A}_{\beta }\) be the global attractor of (1.1) for any fixed β, and let F be a Lyapunov function on \(H_{0}^{1}(\varOmega )\times L^{2}(\varOmega )\) for the semigroup \(\{S(t)\}_{t\geq 0}\) defined by (2.1). Then for any natural number n, there exists β large enough such that

$$\begin{aligned} \gamma \bigl(\mathcal{A}_{\beta }\cap F^{-1} \bigl([\alpha , \infty ) \bigr)\bigr) \geq n. \end{aligned}$$

Corollary 3.5

Under the assumptions of Theorem 3.4, for any natural number n, there exists β large enough such that the semigroup \(\{S(t)\}_{t\geq 0}\) possesses at least n pairs of different fixed points in \(\mathcal{A}_{\beta }\cap F^{-1} ((0,\infty ) )\).

From [5] we know that any compact set A with fractal dimension \(\dim _{F} A=n\) can be mapped into \(\mathbb{R}^{2n+1}\) by a linear odd Hölder-continuous one-to-one projector. Similar to Corollary 1.1 in [17], we have the following corollary.

Corollary 3.6

Suppose assumption \((A)\) holds. Let \(\mathcal{A}_{\beta }\) be the global attractor of (1.1) for any fixed β. Then

$$\begin{aligned} \lim_{\beta \rightarrow \infty }\dim _{F} \mathcal{A}_{\beta }= \infty . \end{aligned}$$