There exist two positive constants $N_1$ and $N_2$ and a decimal $k_0\in (0,1)$ with $(1+k_0)N_1⩽\frac{a}{b}⩽(1-k_0)N_2$ and $(1+k_0)N_1⩽\Gamma (s,x)⩽(1-k_0)N_2$ for $s\in [-\tau ,0],x\in \mathrm{\Omega }$ , such that

(6) $0<N_1⩽u(t,x)⩽N_2,\forall x\in \overline{\mathrm{\Omega }},t⩾-\tau .$

The boundedness assumption in (H1) brings innovations. It ensures that the initial value maintains a certain distance from the upper and lower bounds, so that an impulse with an appropriate frequency and intensity can ensure that the dynamic behavior of the system with such an initial value will not exceed the bounds.

$u_{*}(x)$ is a stationary solution of the system (5) i, f for $(t,x)\in [-\tau ,+\infty )\times \overline{\mathrm{\Omega }}$, $u_{*}(t,x)\equiv u_{*}(x)$, and $u_{*}(x)$ satisfies (H1), and

(7) $\left\{\begin{array}{c}[a-b{u}_{*}(x)]u_{*}(x)+q\Delta u_{*}(x)=0,x\in \mathrm{\Omega },t⩾0,\hfill \\ 0=\frac{\partial u_{*}(x)}{\partial x},t⩾0,x\in \partial \mathrm{\Omega }.\hfill \end{array}\right.$

Now, it is easy to conclude from Definition 1 that $u_{*}\equiv \frac{a}{b}$ is a stationary solution of the system (5). Moreover, letting $U(t,x)=u(t,x)-u_{*}$, the system (5) is translated into

(8) $\left\{\begin{array}{cc}\hfill \frac{\partial U(t,x)}{\partial t}=& -b{U}^2(t,x)-aU(t,x)-c_r[U(t,x)-U(t-\tau (t),x)]+q\Delta U(t,x),x\in \mathrm{\Omega },t⩾0,\hfill \\ \hfill 0=& \frac{\partial U(t,x)}{\partial x},t⩾0,x\in \partial \mathrm{\Omega },\hfill \\ \hfill U(s,x)=& -\frac{a}{b}+\Gamma (s,x),(x,s)\in \mathrm{\Omega }\times [-\tau ,0].\hfill \end{array}\right.$

Here, the positive solution $u_{*}\equiv \frac{a}{b}$ of the ecosystem (5) corresponds to the zero solution of the system (8). Thus, the stabilization of the above-mentioned zero solution will be investigated below. Furthermore, employing an impulse control on the natural ecosystem (5) or (8) results in

(9) $\left\{\begin{array}{cc}\hfill \frac{\partial U(t,x)}{\partial t}=& -b{U}^2(t,x)-aU(t,x)-c_r[U(t,x)-U(t-\tau (t),x)]+q\Delta U(t,x),t\ne t_k,t⩾0,x\in \mathrm{\Omega },\hfill \\ \hfill U(t^{+},x)=& M_{k}U(t^{-},x),t=t_k,k\in \mathbb{N},\hfill \\ \hfill 0=& \frac{\partial U(t,x)}{\partial x},x\in \partial \mathrm{\Omega },t⩾0,\hfill \\ \hfill U(s,x)=& -\frac{a}{b}+\Gamma (s,x)=\xi (s,x),(x,s)\in \mathrm{\Omega }\times [-\tau ,0],\hfill \end{array}\right.$

(10) $\left\{\begin{array}{cc}\hfill \frac{\partial u(t,x)}{\partial t}=& -b{[u(t,x)-\frac{a}{b}]}^2-a[u(t,x)-\frac{a}{b}]-c_r[u(t,x)-u(t-\tau (t),x)]+q\Delta u(t,x),t⩾0,t\ne t_k,x\in \mathrm{\Omega },\hfill \\ \hfill u(t^{+},x)=& M_k[u(t^{-},x)-\frac{a}{b}]+\frac{a}{b},t=t_k,k\in \mathbb{N},\hfill \\ \hfill 0=& \frac{\partial u(t,x)}{\partial x},x\in \partial \mathrm{\Omega },t⩾0,\hfill \\ \hfill \Gamma (s,x)=& u(s,x),(x,s)\in \mathrm{\Omega }\times [-\tau ,0].\hfill \end{array}\right.$

Here, we assume that $0<t_1<t_2<\cdots$, and each $t_k(k\in \mathbb{N})$ represents a fixed impulsive instant. Additionally, $\underset{t\to t_k^{+}}{lim}u(t,x)=u(t_k^{+},x)$, and $u(t_k^{-},x)=u(t_k,x)=\underset{t\to t_k^{-}}{lim}u(t,x)$.

For any given $T>0,$ $U={\{U(t)\}}_{[0,T]}$ is an $L^2(\mathrm{\Omega })$-valued function, and it is called a mild solution of the system (9) if $U(t,x)\in \mathcal{C}([0,T];L^2(\mathrm{\Omega }))$ makes ${\int }_0^t{\parallel U_i(s)\parallel }^{p}ds<\infty ,i=1,2$ hold, and for any $t\in [0,T]$ and $x\in \mathrm{\Omega }$

(11) $\begin{array}{cc}\hfill U(t,x)=& e^{qt\Delta }\sum _{0<t_k<t}{e}^{-q{t}_k\Delta }(M_k-1)U(t_k,x)+{\int }_0^t{e}^{q(t-s)\Delta }\left(-b{U}^2(s,x)-aU(s,x)-c_r[U(s,x)-U(s-\tau (s),x)]\right)ds\hfill \\ & +e^{qt\Delta }\xi (0,x),t⩾0,\hfill \end{array}$

$\xi (s,x)=U(s,x),x\in \mathrm{\Omega },s\in [-\tau ,0],$

$0=\frac{\partial U}{\partial \nu },t⩾0,x\in \partial \mathrm{\Omega }.$

Definition 2 is well defined in view of [23,24]; particularly, the considerations about the impulsive items in [24] provide a useful hint for designing Definition 2.

There are two constants $M>0$ and $\gamma >0$ such that $\parallel e^{t\Delta }{\parallel }_2⩽M{e}^{-\gamma t}$, where $\parallel e^{t\Delta }{\parallel }_2=\underset{\parallel w\parallel =1}{sup}\parallel e^{t\Delta }w\parallel$ (see [23]).

(see, for example, [14]). $\mathrm{\Omega }\subset R^m$ is a bounded domain, and its smooth boundary $\partial \mathrm{\Omega }$ is of class ${\mathcal{C}}^2$. $\theta (x)\in H_0^1(\mathrm{\Omega })$ is a real-valued function, and $\frac{\partial \theta (x)}{\partial \nu }{|}_{\partial \mathrm{\Omega }}=0$. Then,

${\int }_{\mathrm{\Omega }}{|\nabla \theta (x)|}^{2}dx⩾{\lambda }_1{\int }_{\mathrm{\Omega }}{|\theta (x)|}^{2}dx,$

$\left\{\begin{array}{c}\lambda \theta -\Delta \theta =0,x\in \mathrm{\Omega },\hfill \\ \frac{\partial \theta (x)}{\partial \nu }=0,x\in \partial \mathrm{\Omega },\hfill \end{array}\right.$

([36]) If f is a contraction mapping on a complete metric space $\mathcal{H}$, there must exist a unique point $u\in \mathcal{H}$, satisfying $f(u)=u$.

Suppose (H1) holds. For all $r(t)=r\in S$, the system (5) possesses a positive stationary solution $u_{*}\equiv \frac{a}{b}$ for all $(t,x)\in [-\tau ,+\infty )\times \overline{\mathrm{\Omega }}$. If, in addition, the following condition is satisfied:

(12) $a<{\lambda }_{1}q+2b{N}_1$

Obviously, for $(t,x)\in [-\tau ,0]\times \overline{\mathrm{\Omega }}$, $u_{*}\equiv \frac{a}{b}$ makes the following equations hold:

$q\Delta u_{*}+u_{*}[a-b{u}_{*}]=0,t⩾0,x\in \mathrm{\Omega },$

$\frac{\partial u_{*}}{\partial x}=0,x\in \partial \mathrm{\Omega },t⩾0.$

Thus, Definition 1 yields that $u_{*}>0$ defined in Theorem 1 is the unique stationary solution of the system (5).

Below, we claim that $u_{*}$ is the unique stationary solution of the ecosystem (5).

Indeed, if $u_{*}$ and $v_{*}(x)$ are two different stationary solutions of the system (5), then Poincare inequality and the boundary condition yield

(13)$a{\int }_{\mathrm{\Omega }}{(u_{*}-v_{*}(x))}^{2}dx-b{\int }_{\mathrm{\Omega }}{(u_{*}-v_{*}(x))}^2(u_{*}+v_{*}(x))dx⩾{\lambda }_{1}q{\int }_{\mathrm{\Omega }}{|u_{*}-v_{*}(x)|}^{2}dx.$

The condition (12), Definition 2 and the continuity of $u_{*}$ and $v_{*}$ lead to

$a{\int }_{\mathrm{\Omega }}{(u_{*}-v_{*}(x))}^{2}dx-b{\int }_{\mathrm{\Omega }}{(u_{*}-v_{*}(x))}^2(u_{*}+v_{*}(x))dx<{\lambda }_1{\int }_{\mathrm{\Omega }}{|u_{*}-v_{*}(x)|}^{2}dx,$

This completes the proof. □

As far as our knowledge, Theorem 1 is the first theorem to provide the unique existence of the stationary solution of a single-species ecosystem under a Neumann boundary value.

This paper provides the unique existence of a stationary solution of a reaction–diffusion system. However, there are many previous articles related to reaction–diffusion systems that only involve the existence of the equilibrium point. For example, in [14], only the unique existence of the constant equilibrium point of a reaction–diffusion system with a Neumann boundary value was given, but the stationary solutions of a reaction–diffusion system may include the non-constant stationary solutions. Because the solution $u(t,x)$ of a reaction–diffusion system involves not only the time variable t but also the space variable x, its stationary solution should be $u_{*}(x)$, independent of the time variable t. Obviously, $u_{*}(x)$ must not be a constant equilibrium point, which may be dependent upon the space variable x. Thereby, it is not inappropriate to prove that the equilibrium point is the unique constant equilibrium point in [14]. It must be proved that it is the unique stationary solution, just like that of this paper. A similar example can also be found in [12].

Note that the system (10) has the same elliptic equation as that of the system (5), and hence, each stationary solution of the system (5) is that of the system (10), and vice versa. i.e., Theorem 1 shows that $u_{*}\equiv \frac{a}{b}$ is also the unique stationary solution of the system (10). Next, the global stability of the stationary solution $u_{*}\equiv \frac{a}{b}$ should be investigated.

Set $p⩾1$. Suppose all the conditions of Theorem 1 hold. Assume, in addition, the condition (H2) holds, and

(14) $0<{\varpi }_r<1,r(t)=r\in \mathcal{S};$

(15) ${\varpi }_r={\left[4^{p-1}\left(b{(\frac{2M{N}_0}{q\gamma })}^p+(a+c_r){(\frac{M}{q\gamma })}^p+c_r{(\frac{M}{q\gamma })}^p+M^{2p}(\underset{k}{max}|M_k-1{|)}^p{\left(1+\frac{1}{q\gamma \mu }\right)}^p\right)\right]}^{\frac{1}{p}}.$

Let the normed space $\mathcal{H}$ be the functions space consisting of functions $g(t,x):[-\tau ,+\infty )\times \overline{\mathrm{\Omega }}\to [N_1-\frac{a}{b},N_2-\frac{a}{b}]$, where g satisfies:

• (A1) g is pth moment continuous at $t⩾0$ with $t\ne t_k(k\in \mathbb{N})$;

• (A2) for any given $x\in \mathrm{\Omega }$, $\underset{t\to t_k^{-}}{lim}g(t,x)$ and $\underset{t\to t_k^{+}}{lim}g(t,x)$ exist, and $\underset{t\to t_k^{-}}{lim}g(t,x)=g(t_k,x)$;

• (A3) $g(s,x)=\xi (s,x),\forall s\in [-\tau ,0],x\in \mathrm{\Omega }$;

• (A4) $e^{\alpha t}{\parallel g(t)\parallel }^p\to 0$ as $t\to +\infty$, where $\alpha$ is a positive scalar with $0<\alpha <q\gamma$.

It is easy to verify that $\mathcal{H}$ is a complete metric space equipped with the following distance:

(16)$\mathrm{dist}\left(U,V\right)={\left(\underset{t⩾-\tau }{sup}{\parallel U(t,x)-V(t,x)\parallel }^p\right)}^{\frac{1}{p}},\forall U,V\in \mathcal{H}.$

Construct an operator $\mathcal{\Theta }$ such that, for any given $U\in \mathcal{H},$

(17)$\left\{\begin{array}{cc}\hfill \mathcal{\Theta }(U)(t,x)=& e^{qt\Delta }\sum _{0<t_k<t}{e}^{-q{t}_k\Delta }(M_k-1)U(t_k,x)+{\int }_0^t{e}^{q(t-s)\Delta }(-b{U}^2(s,x)-aU(s,x)-c_r[U(s,x)\hfill \\ & -U(s-\tau (s),x)])ds+e^{qt\Delta }\xi (0,x),t⩾0,\hfill \\ \hfill 0=& \frac{\partial \mathcal{\Theta }(U)}{\partial \nu },x\in \partial \mathrm{\Omega },t⩾0,\hfill \\ \hfill \xi (s,x)=& \mathcal{\Theta }(U)(s,x),s\in [-\tau ,0],x\in \mathrm{\Omega }.\hfill \end{array}\right.$

Below, we want to prove that $\mathcal{\Theta }:\mathcal{H}\to \mathcal{H}$, and it takes four steps to achieve the goal.

Step 1. It is claimed that, for $U\in \mathcal{H}$, $\mathcal{\Theta }(U)$ must be pth moment continuous at $t⩾0$ with $t\ne t_k(k\in \mathbb{N})$.

Indeed, $U\in [N_1-\frac{a}{b},N_2-\frac{a}{b}]$ means the boundedness of U, and let $\delta$ be a scalar small enough; a routine proof yields that if $\delta \to 0,$ for $t\in [0,+\infty )\backslash {\{t_k\}}_{k=1}^{\infty }$,

(18)$\begin{array}{c}{\parallel \mathcal{\Theta }(U)(t,x)-\mathcal{\Theta }(U)(t+\delta ,x)\parallel }^p⩽4^{p-1}\parallel e^{qt\Delta }\xi (0,x)-e^{q(t+\delta )\Delta }{\xi (0,x)\parallel }^p\hfill \\ +4^{p-1}\parallel {\int }_0^t{e}^{q(t-s)\Delta }[-aU(s,x)-b{U}^2(s,x)]ds-{\int }_0^{t+\delta }{e}^{q(t+\delta -s)\Delta }[-aU(s,x)-b{U}^2(s,x)]{ds\parallel }^p\hfill \\ +4^{p-1}\parallel {\int }_0^t{e}^{q(t-s)\Delta }[c_r(U(s,x)-U(s-\tau (s),x))]ds-{\int }_0^{t+\delta }{e}^{q(t+\delta -s)\Delta }[c_r(U(s,x)-U(s-\tau (s),x))]{ds\parallel }^p\hfill \\ +4^{p-1}{\parallel e^{qt\Delta }\sum _{0<t_k<t}{e}^{-q{t}_k\Delta }(M_k-1)U(t_k,x)-e^{q(t+\delta )\Delta }\sum _{0<t_k<t+\delta }{e}^{-q{t}_k\Delta }(M_k-1)U(t_k,x)\parallel }^p\to 0,\hfill \end{array}$

Step 2. $\mathcal{\Theta }(U)$ satisfies (A2), where $U\in \mathcal{H}$.

In fact, for $U\in \mathcal{H}$, people can easily see from (17) that $\underset{t\to t_k^{+}}{lim}\mathcal{\Theta }(U)(t,x)$ and $\underset{t\to t_k^{-}}{lim}\mathcal{\Theta }(U)(t,x)$ exist, and $\mathcal{\Theta }(U)(t_k,x)=\underset{t\to t_k^{-}}{lim}\mathcal{\Theta }(U)(t,x)$, which verifies (A2).

Step 3. $\mathcal{\Theta }(U)$ satisfies (A3), where $U\in \mathcal{H}$. Indeed, the third equation of (17) verifies (A3) directly.

Step 4. Verifying (A4), i.e., for $U\in \mathcal{H}$, verifying

(19)$e^{\alpha t}\parallel \mathcal{\Theta }(U)(t){\parallel }^p\to 0,\mathrm{if}t\to +\infty .$

Indeed,

(20)$\begin{array}{cc}& e^{\alpha t}{\parallel \mathcal{\Theta }(U)(t,x)\parallel }^p=e^{\alpha t}\parallel e^{qt\Delta }\xi (0,x)+{\int }_0^t{e}^{q(t-s)\Delta }\left(-aU(s,x)-b{U}^2(s,x)-c_r[U(s,x)-U(s-\tau (s),x)]\right)ds\hfill \\ & +e^{qt\Delta }\sum _{0<t_k<t}{e}^{-q{t}_k\Delta }(M_k-1)U(t_k,x){\parallel }^p\hfill \\ \hfill ⩽& 5^{p-1}{e}^{\alpha t}\parallel e^{qt\Delta }\xi (0,x){\parallel }^p+5^{p-1}{e}^{\alpha t}\parallel {\int }_0^t{e}^{q(t-s)\Delta }[-aU(s,x)-b{U}^2(s,x)]{ds\parallel }^p+5^{p-1}{e}^{\alpha t}\parallel {\int }_0^t{e}^{q(t-s)\Delta }{c}_{r}U(s,x){ds\parallel }^p\hfill \\ & +5^{p-1}{e}^{\alpha t}\parallel {\int }_0^t{e}^{q(t-s)\Delta }{c}_{r}U(s-\tau (s),x){ds\parallel }^p+5^{p-1}{e}^{\alpha t}{\parallel e^{qt\Delta }\sum _{0<t_k<t}{e}^{-q{t}_k\Delta }(M_k-1)U(t_k,x)\parallel }^p,t⩾0,\hfill \end{array}$

Moreover,

(21)$e^{\alpha t}\parallel e^{qt\Delta }{\xi (0,x)\parallel }^p⩽M^p{e}^{\alpha t}{e}^{-\gamma qt}{\parallel \xi (0,x)\parallel }^p\to 0,\mathrm{if}t\to +\infty .$

$U\in \mathcal{H}$ means $U\in [N_1-\frac{a}{b},N_2-\frac{a}{b}]$, and

(22)$U^2⩽N_0|U|,\mathrm{where}{N}_0=max\{|N_1-\frac{a}{b}|,N_2-\frac{a}{b}\}.$

The Holder inequality yields

(23)$\begin{array}{cc}& e^{\alpha t}{\parallel {\int }_0^t{e}^{q(t-s)\Delta }\left(-aU(s,x)-b{U}^2(s,x)\right)ds\parallel }^p\hfill \\ \hfill ⩽& 2^{p-1}{M}^p\left[a^p{(\frac{1}{q\gamma })}^{p-1}{\int }_0^t{e}^{-(q\gamma -\alpha )(t-s)}{e}^{\alpha s}\parallel U(s,x){\parallel }^{p}ds+b^p{N}_0^p{(\frac{1}{q\gamma })}^{p-1}{\int }_0^t{e}^{-q\gamma (t-s)}{\parallel U\parallel }^{p}ds\right].\hfill \end{array}$

On the other hard, $e^{\alpha t}{\parallel U_i(t)\parallel }^p\to 0$ means that, for any $\epsilon >0$, there exists $t^{*}>0$ such that all $e^{\alpha t}{\parallel U_i(t)\parallel }^p<\epsilon .$ Therefore,

$\begin{array}{cc}& {\int }_0^t{e}^{-(q\gamma -\alpha )(t-s)}{e}^{\alpha s}{\parallel U(s,x)\parallel }^{p}ds\hfill \\ \hfill ⩽& \underset{s\in [0,t^{*}]}{max}(e^{\alpha s}{\parallel U(s,x)\parallel }^p)e^{-(q\gamma -\alpha )t}\frac{1}{q\gamma -\alpha }{e}^{(q\gamma -\alpha )t^{*}}+\epsilon \frac{1}{q\gamma -\alpha },\hfill \end{array}$

(24)${\int }_0^t{e}^{-(q\gamma -\alpha )(t-s)}{\parallel U(s,x)\parallel }^p{e}^{\alpha s}ds\to 0,t\to +\infty .$

(25)$e^{\alpha t}{\parallel {\int }_0^t{e}^{q(t-s)\Delta }[-aU(s,x)-b{U}^2(s,x)]ds\parallel }^p,t\to +\infty .$

(26)$e^{\alpha t}{\parallel {\int }_0^t{e}^{q(t-s)\Delta }{c}_{r}U(s,x)ds\parallel }^p,,t\to +\infty .$

Since $U(s,x)=\xi (s,x)$ is bounded on $[-\tau ,0]\times \mathrm{\Omega }$, it is not difficult to similarly prove

(27)$e^{\alpha t}{\parallel {\int }_0^t{e}^{q(t-s)\Delta }{c}_{r}U(s-\tau (s),x)ds\parallel }^p,t\to +\infty .$

Next, using the definition of the Riemann integral ${\int }_a^b{e}^{s}ds$ results in

(28)$\begin{array}{cc}& e^{\alpha t}\parallel e^{qt\Delta }\sum _{0<t_k<t}{e}^{-q{t}_k\Delta }(M_k-1)U(t_k,x){\parallel }^p\hfill \\ \hfill ⩽& 2^{p-1}\underset{k}{max}|M_k-1|\left[e^{-(pq\gamma -\alpha )t}{\left(\sum _{0<t_k⩽t^{*}}{e}^{q\gamma t_k}\parallel U(t_k,x)\parallel \right)}^p+\epsilon \frac{1}{{(q\gamma -\frac{\alpha }{p})}^p}\right]\to 0.\hfill \end{array}$

Combining (20)–(28) yields (19).

It follows from the above four steps that

(29)$\mathcal{\Theta }(\mathcal{H})\subset \mathcal{H}.$

Finally, we claim that $\mathcal{\Theta }$ is a contractive mapping on $\mathcal{H}$.

Indeed, for any $U,V\in \mathcal{H}$, the Holder inequality and (H2) yield

(30)$\begin{array}{cc}& \parallel {\int }_0^t{e}^{q(t-s)\Delta }{[V(s,x)-U(s,x)]ds\parallel }^p\hfill \\ \hfill ⩽& {\left(M{\int }_0^t{e}^{-q\gamma (t-s)}\parallel V(s,x)-U(s,x)\parallel ds\right)}^p\hfill \\ \hfill ⩽& M^p{\left({(\frac{1}{q\gamma })}^{\frac{p-1}{p}}[\underset{t⩾-\tau }{sup}\parallel U(t,x)-V(t,x){{\parallel }^p]}^{\frac{1}{p}}{(\frac{1}{q\gamma })}^{\frac{1}{p}}\right)}^p\hfill \\ \hfill ⩽& {(\frac{M}{q\gamma })}^p{[\mathrm{dist}(U,V)]}^p.\hfill \end{array}$

Similarly,

(31)$\begin{array}{cc}& \parallel {\int }_0^t{e}^{q(t-s)\Delta }[U^2(s,x)-V^2(s,x)]{ds\parallel }^p\hfill \\ \hfill ⩽& {\left(2M{N}_0{\int }_0^t{e}^{-q\gamma (t-s)}\parallel U(s,x)-V(s,x)\parallel ds\right)}^p\hfill \\ \hfill ⩽& {(\frac{2M{N}_0}{q\gamma })}^p{[\mathrm{dist}(U,V)]}^p,\hfill \end{array}$

(32)$\parallel {\int }_0^t{e}^{q(t-s)\Delta }{[V(s-\tau (s),x)-U(s-\tau (s),x)]ds\parallel }^p⩽{(\frac{M}{q\gamma })}^p{[\mathrm{dist}(U,V)]}^p$

Assume $t_{j-1}<t⩽t_j$; then, the definition of the Riemann integral ${\int }_a^b{e}^{s}ds$ yields

(33)$\begin{array}{cc}& \parallel e^{qt\Delta }\sum _{0<t_k<t}{e}^{-q{t}_k\Delta }(M_k-1)[U(t_k,x)-V(t_k,x)]{\parallel }^p\hfill \\ \hfill ⩽& M^{2p}(\underset{k}{max}|M_k-{1|)}^p{\left[e^{-q\gamma t}\left(e^{q\gamma t_{j-1}}+\frac{1}{\mu }\sum _{0<t_k⩽t_{j-2}}{e}^{q\gamma t_k}(t_{k+1}-t_k)\right)·\mathrm{dist}(U,V)\right]}^p\hfill \\ \hfill ⩽& M^{2p}(\underset{k}{max}|M_k-1{|)}^p{\left(1+\frac{1}{q\gamma \mu }\right)}^p·{[\mathrm{dist}(U,V)]}^p.\hfill \end{array}$

It follows from (30)–(33) that

$\begin{array}{cc}& {\parallel \mathcal{\Theta }(U)-\mathcal{\Theta }(V)\parallel }^p\hfill \\ \hfill ⩽& 4^{p-1}b\parallel {\int }_0^t{e}^{q(t-s)\Delta }[U^2(s,x)-V^2(s,x)]{ds\parallel }^p+4^{p-1}(a+c_r)\parallel {\int }_0^t{e}^{q(t-s)\Delta }[U(s,x)-V(s,x)]{ds\parallel }^p\hfill \\ & +4^{p-1}\parallel {\int }_0^t{e}^{q(t-s)\Delta }{e}^{qt\Delta }\sum _{0<t_k<t}{e}^{-q{t}_k\Delta }(M_k-1)[U(t_k,x)-V(t_k,x)]{\parallel }^p\hfill \\ & +4^{p-1}{c}_r{\parallel {\int }_0^t{e}^{q(t-s)\Delta }[U(s-\tau (s),x)-V(s-\tau (s),x)]ds\parallel }^p⩽\hfill \\ \hfill ⩽& 4^{p-1}{[\mathrm{dist}(U,V)]}^p\left((a+c_r){(\frac{M}{q\gamma })}^p+b{(\frac{2M{N}_0}{q\gamma })}^p+c_r{(\frac{M}{q\gamma })}^p+M^{2p}(\underset{k}{max}|M_k-1{|)}^p{\left(1+\frac{1}{q\gamma \mu }\right)}^p\right),\hfill \end{array}$

$\mathrm{dist}(\mathcal{\Theta }(V),\mathcal{\Theta }(U))⩽\mathrm{dist}(U,V)(\underset{r\in S}{max}{\varpi }_r),\forall U,V\in \mathcal{H}.$

Now, the definition of ${\varpi }_r$ implies that $\mathcal{\Theta }:\mathcal{H}\to \mathcal{H}$ is contractive such that there must exist the fixed point U of $\mathcal{\Theta }$ in $\mathcal{H}$, which means that U is the solution of the system (9), satisfying $e^{\alpha t}\parallel U{\parallel }^p\to 0$, $t\to +\infty$ so that $e^{\alpha t}\parallel u-u_{*}{\parallel }^p\to 0$, $t\to +\infty$. Therefore, the zero solution of the system (9) is the globally exponential stability in the pth moment; equivalently, $u_{*}\equiv \frac{a}{b}$ of the system (10) is the globally exponential stability in the pth moment. □

To the best of our knowledge, this is the first paper to employ impulsive control and the Laplacian semigroup to globally stabilize a single-species ecosystem.

This paper reports the global stability of a single-species ecosystem, while the stability in [3] did not involve the global one. This means that the stability in [3] depends heavily on the choice of initial value, while the global stability does not need such a choice. On the other hand, Equation (5) involves the space state, while the models in [3] did not involve the spatial location. In fact, population migration has a great impact on population stability, so the spatial state should be considered in the ecosystem model.

Set $S=\{1,2\}$, $c_1=0.03,c_2=0.06,{\gamma }_{11}=-0.23,{\gamma }_{12}=0.23,{\gamma }_{21}=0.16,$ and ${\gamma }_{22}=-0.16$. Assume $\Gamma (s,x)\equiv 0.453,$ $q=0.2,a=0.1692,b=0.4,N_1=0.3,and{N}_2=0.523,$; then, $N_0=0.123,u_{*}=0.423.$ Suppose, in addition, $\mathrm{\Omega }=(0,\pi ),$ $\tau =0.5\equiv \tau (t)$ for all $t⩾0.$ Then, by computing the eigenfunctions of $-\Delta$, one can obtain $\parallel e^{t\Delta }\parallel ⩽e^{-{\pi }^{2}t},t⩾0$, and so $\gamma ={\pi }^2={\lambda }_1,M=1.$ Direct computation yields

$0.1692=a<2.2139={\lambda }_{1}q+2b{N}_1,$

This example uses all the data provided in Example 1. Assume, in addition, $p=1.005,M_k\equiv 1.02,\mu =5$; obviously, the condition (H2) holds in Example 1. Moreover, we can obtain, by direct calculations, that

$0<{\varpi }_1={\left[4^{p-1}\left((a+c_1){(\frac{M}{q\gamma })}^p+b{(\frac{2M{N}_0}{q\gamma })}^p+c_1{(\frac{M}{q\gamma })}^p+M^{2p}(\underset{k}{max}|M_k-1{|)}^p{\left(1+\frac{1}{q\gamma \mu }\right)}^p\right)\right]}^{\frac{1}{p}}<1,$

$0<{\varpi }_2={\left[4^{p-1}\left((a+c_2){(\frac{M}{q\gamma })}^p+b{(\frac{2M{N}_0}{q\gamma })}^p+c_2{(\frac{M}{q\gamma })}^p+M^{2p}(\underset{k}{max}|M_k-1{|)}^p{\left(1+\frac{1}{q\gamma \mu }\right)}^p\right)\right]}^{\frac{1}{p}}<1.$

Obviously, Example 2 illuminates that Theorem 2 is better than [22] (Theorem 4.2) due to reducing the conservatism of the algorithm, because the pulse intensity in Theorem 2 does not require the pulse intensity to be less than 1 but allows it to be greater than 1, while the latter requires that the pulse intensity is less than 1 (see [22] (Theorem 4.2)).

In Example 1 and Example 2, it follows from $0.3=N_1⩽u⩽N_2=0.523$ and $u_{*}=0.423$ that $0⩽|U|⩽0.123$. A computer simulation of the dynamics of the state $U(t,x)$ of the system (9) illuminated the feasibility of Theorems 1 and 2 (see Figure 1 and Figure 2). In addition, (H1) is the only common condition in much related literature (see, for example, [37] (Definition 1)).