Existence of nonoscillatory solutions tending to zero of third-order neutral dynamic equations on time scales

We study the existence of nonoscillatory solutions tending to zero of a class of third-order nonlinear neutral dynamic equations on time scales by employing Krasnoselskii’s fixed point theorem. Two examples are given to illustrate the significance of the conclusions.

In this paper, we consider the existence of nonoscillatory solutions tending to zero of a class of third-order nonlinear neutral dynamic equations

on a time scale \(\mathbb{T}\) satisfying \(\sup \mathbb{T}=\infty \), where \(t\in [t_{0},\infty )_{\mathbb{T}}=[t_{0},\infty )\cap {\mathbb{T}}\) with \(t_{0}\in \mathbb{T}\). The following conditions are assumed to hold throughout this paper:

1. (C1)

   \(r_{1}, r_{2}\in \mathrm{ C}_{\mathrm{rd}}([t_{0},\infty )_{\mathbb{T}}, (0, \infty ))\);

2. (C2)

   \(p\in \mathrm{ C}_{\mathrm{rd}}([t_{0},\infty )_{\mathbb{T}}, \mathbb{R})\) and \(\lim_{t \rightarrow \infty }p(t)=p_{0}\), where \(|p_{0}|<1\);

3. (C3)

   \(g,h\in \mathrm{ C}_{\mathrm{rd}}([t_{0},\infty )_{\mathbb{T}}, \mathbb{T})\), \(g(t)\leq t\), and \(\lim_{t \rightarrow \infty }g(t)=\lim_{t \rightarrow \infty }h(t)= \infty \); if \(p_{0}\in (-1,0]\), then there exists a sequence \(\{c_{k}\}_{k\geq 0}\) such that \(\lim_{k \rightarrow \infty }c_{k}=\infty \) and \(g(c_{k+1})=c_{k}\);

4. (C4)

   \(f\in \mathrm{ C}([t_{0},\infty )_{\mathbb{T}}\times \mathbb{R}, \mathbb{R})\), \(f(t,x)\) is nondecreasing in x, and \(xf(t,x)>0\) for \(x\neq 0\).

The details of the theory of time scales can be found in [1–4, 8, 9] and hence they are omitted here. In recent years, the existence of nonoscillatory solutions of neutral dynamic equations on time scales has been studied successively in [6, 7, 11, 13–17]. Zhu and Wang [17] were concerned with a first-order neutral dynamic equation

Afterward, Deng and Wang [6] and Gao and Wang [7] investigated a second-order neutral dynamic equation

under the different assumptions \(\int _{t_{0}}^{\infty }1/r(t)\Delta t=\infty \) and \(\int _{t_{0}}^{\infty }1/r(t)\Delta t<\infty \), respectively. Furthermore, Qiu [11] studied (1.1) with \(\int _{t_{0}}^{\infty }1/r_{1}(t)\Delta t=\int _{t_{0}}^{\infty }1/r_{2}(t) \Delta t=\infty \), whereas other cases of the convergence and divergence of \(\int _{t_{0}}^{\infty }1/r_{1}(t)\Delta t\) and \(\int _{t_{0}}^{\infty }1/r_{2}(t)\Delta t\) were considered in [14–16]. Similar sufficient conditions for the existence of nonoscillatory solutions tending to zero of neutral dynamic equations have been presented. However, it is not easy to find a necessary condition for equations to have a nonoscillatory solution tending to zero asymptotically.

Mojsej and Tartal’ová [10] studied the asymptotic behavior of nonoscillatory solutions to a third-order differential equation

They stated some necessary and sufficient conditions ensuring the existence of nonoscillatory solutions tending to zero. Motivated by [10], Qiu [12] studied the existence of nonoscillatory solutions tending to zero of (1.1) under the conditions \(0\leq p_{0}<1\) and \(g(t)\geq t\). The conclusions extend and improve the results reported in the papers [11, 14–16].

The purpose of this paper is to further discuss the same problem of (1.1) with \(|p_{0}|<1\) and \(g(t)\leq t\). The existence of nonoscillatory solutions tending to zero of (1.1) is established by employing Krasnoselskii’s fixed point theorem. Finally, two examples are presented to show the versatility of the conclusions.

Let \(\mathrm{ BC}[T_{0},\infty )_{\mathbb{T}}\) denote the Banach space of all bounded continuous functions mapping \([T_{0},\infty )_{\mathbb{T}}\) into \(\mathbb{R}\) with the norm \(\|x\|=\sup_{t\in [T_{0},\infty )_{\mathbb{T}}}|x(t)|\). For the sake of convenience, we define

and state the following lemmas which will be used in the sequel.

Lemma 2.1

(see [5, Krasnoselskii’s fixed point theorem])

LetXbe a Banach space andΩbe a bounded, convex, and closed subset ofX. If there exist two operators\(U,V:\varOmega \rightarrow X\)such that\(Ux+Vy\in \varOmega \)for all\(x,y\in \varOmega \), whereUis a contraction mapping andVis completely continuous, then\(U+V\)has a fixed point inΩ.

Lemma 2.2

Suppose thatxis an eventually positive solution of (1.1) and there exists a constant\(a\geq 0\)such that\(\lim_{t\rightarrow \infty }z(t)=a\). Then

The proof is similar to those of [6, Lemma 2.3], [7, Theorem 1], and [17, Theorem 7], and thus is omitted.

In this section, our existence criteria for eventually positive solutions tending to zero as \(t\rightarrow \infty \) of (1.1) are established by employing Krasnoselskii’s fixed point theorem.

Theorem 3.1

Assume that

where

which satisfies\(\lim_{t\rightarrow \infty }H_{1}(g(t))/H_{1}(t)=1\). Then (1.1) has an eventually positive solutionxwith\(\lim_{t\rightarrow \infty }x(t)=0\), where\(r_{2}z^{\Delta }\)and\(r_{1} (r_{2}z^{\Delta } )^{\Delta }\)are both eventually negative.

Proof

Suppose that (3.1) holds. There will be two cases to be considered.

Case (i). \(0\leq p_{0}<1\). Take \(p_{1}\) such that \(p_{0}< p_{1}<(1+4p_{0})/5<1\). When \(p_{0}>0\), choose a sufficiently large \(T_{0}\in [t_{0},\infty )_{\mathbb{T}}\) such that

When \(p_{0}=0\), choose \(p_{1}\) such that \(|p(t)|\leq p_{1}\leq 1/13\) for \(t\in [T_{0},\infty )_{\mathbb{T}}\). In view of (C3), there exists a \(T_{1}\in (T_{0},\infty )_{\mathbb{T}}\) such that \(g(t)\geq T_{0}\) and \(h(t)\geq T_{0}\) for \(t\in [T_{1},\infty )_{\mathbb{T}}\).

Define

It is easy to prove that \(\varOmega _{1}\) is a bounded, convex, and closed subset of \(\mathrm{ BC}[T_{0},\infty )_{\mathbb{T}}\). Define \(U_{1}\) and \(V_{1}\): \(\varOmega _{1}\rightarrow \mathrm{ BC}[T_{0},\infty )_{\mathbb{T}}\) as follows:

We can prove that \(U_{1}\) and \(V_{1}\) satisfy all conditions in Lemma 2.1. The proof is expatiatory but similar to those of [6, Theorem 2.5], [7, Theorem 2], [12, Theorem 3.1], and [17, Theorem 8]; so we omit it here. By virtue of Lemma 2.1, there exists an \(x\in \varOmega _{1}\) such that \((U_{1}+V_{1})x=x\). Hence, for \(t\in [T_{1},\infty )_{\mathbb{T}}\), we have

Since

and

we arrive at \(\lim_{t\rightarrow \infty }z(t)=0\), which implies that \(\lim_{t\rightarrow \infty }x(t)=0\) with the help of Lemma 2.2. For \(t\in [T_{1},\infty )_{\mathbb{T}}\), we obtain

and

Case (ii). \(-1< p_{0}<0\). Take \(p_{1}\) satisfying \(-p_{0}< p_{1}<(1-4p_{0})/5<1\). Choose a sufficiently large \(T_{0}\in [t_{0},\infty )_{\mathbb{T}}\) such that (3.2) holds and

Proceeding as in the proof of Case (i), define \(V_{1}\) as in (3.3) and \(U'_{1}\) on \(\varOmega _{1}\) as follows:

Similarly, there exists an \(x\in \varOmega _{1}\) such that \((U'_{1}+V_{1})x=x\). For \(t\in [T_{1},\infty )_{\mathbb{T}}\), we have

and we arrive at the same conclusions as in Case (i). This completes the proof. □

Theorem 3.2

Assume that

Then (1.1) has no eventually positive solutionsxsatisfying that\(r_{2}z^{\Delta }\)and\(r_{1} (r_{2}z^{\Delta } )^{\Delta }\)are both eventually negative.

Proof

Suppose that x is an eventually positive solution of (1.1), and there exists a \(T_{0}\in [t_{0},\infty )_{\mathbb{T}}\) such that

From (C3), there exists a \(T_{1}\in (T_{0},\infty )_{\mathbb{T}}\) such that \(h(t)\geq T_{0}\) for \(t\in [T_{1},\infty )_{\mathbb{T}}\). Integrating (1.1) from \(T_{1}\) to s, \(s\in [\sigma (T_{1}),\infty )_{\mathbb{T}}\), by (C4) we obtain

which yields

Integrating (3.4) from \(T_{1}\) to v, \(v\in [\sigma (T_{1}),\infty )_{\mathbb{T}}\), we get

or

Integrating (3.5) from \(T_{1}\) to t, \(t\in [\sigma (T_{1}),\infty )_{\mathbb{T}}\), we obtain

Letting \(t\rightarrow \infty \), we have \(z(t)\rightarrow -\infty \). From (2.1), it follows that \(p_{0}\in (-1,0]\), and then there exist a \(T_{2}\in [T_{1},\infty )_{\mathbb{T}}\) and a \(p_{1}\) with \(-p_{0}< p_{1}<1\) such that \(z(t)<0\) or

By (C3), choose some positive integer \(k_{0}\) such that \(c_{k}\in [T_{2},\infty )_{\mathbb{T}}\) for all \(k\geq k_{0}\). Then, for any \(k\geq k_{0}+1\), we have

This inequality implies that \(\lim_{k\rightarrow \infty }x(c_{k})=0\). It follows from (2.1) that \(\lim_{k\rightarrow \infty }z(c_{k})=0\) which contradicts \(z(t)\rightarrow -\infty \) as \(t\rightarrow \infty \). The proof is complete. □

Theorem 3.3

Assume that

where

which satisfies\(\lim_{t\rightarrow \infty }H_{2}(g(t))/H_{2}(t)=1\). Then (1.1) has an eventually positive solutionxwith\(\lim_{t\rightarrow \infty }x(t)=0\), where\(r_{2}z^{\Delta }\)is eventually negative and\(r_{1} (r_{2}z^{\Delta } )^{\Delta }\)is eventually positive.

Proof

Suppose that (3.6) holds. There are two cases to be considered.

Case (i). \(0\leq p_{0}<1\). Take \(p_{1}\) as in Case (i) of Theorem 3.1. When \(p_{0}>0\), choose a sufficiently large \(T_{0}\in [t_{0},\infty )_{\mathbb{T}}\) such that

When \(p_{0}=0\), choose \(p_{1}\) such that \(|p(t)|\leq p_{1}\leq 1/13\) for \(t\in [T_{0},\infty )_{\mathbb{T}}\). By virtue of (C3), there exists a \(T_{1}\in (T_{0},\infty )_{\mathbb{T}}\) such that \(g(t)\geq T_{0}\) and \(h(t)\geq T_{0}\) for \(t\in [T_{1},\infty )_{\mathbb{T}}\).

Define

and \(U_{2}\), \(V_{2}\): \(\varOmega _{2}\rightarrow \mathrm{ BC}[T_{0},\infty )_{\mathbb{T}}\) as follows:

The remainder of the proof is similar to that of Theorem 3.1 and so is omitted. By Lemma 2.1, there exists an \(x\in \varOmega _{2}\) such that \((U_{2}+V_{2})x=x\). For \(t\in [T_{1},\infty )_{\mathbb{T}}\), we have

Since

and

we get \(\lim_{t\rightarrow \infty }z(t)=0\), which implies that \(\lim_{t\rightarrow \infty }x(t)=0\) due to Lemma 2.2. For \(t\in [T_{1},\infty )_{\mathbb{T}}\), we obtain

and

Case (ii). \(-1< p_{0}<0\). Introduce \(\mathrm{ BC}[T_{0},\infty )_{\mathbb{T}}\) and its subset \(\varOmega _{2}\) as in (3.7). Define \(V_{2}\) as in (3.8) and \(U'_{2}\) on \(\varOmega _{2}\) as follows:

The following proof is similar to Case (i) and we omit it here. There exists an \(x\in \varOmega _{2}\) such that \((U'_{2}+V_{2})x=x\). For \(t\in [T_{1},\infty )_{\mathbb{T}}\), we have

and obtain the similar results as in Case (i). This completes the proof. □

In this section, two examples are presented to show the applications of our results. The first example is given to illustrate Theorem 3.1.

Example 4.1

Let \(\mathbb{T}=\bigcup_{n=1}^{\infty }[3n-2,3n]\). For \(t\in [4,\infty )_{\mathbb{T}}\), consider

Here, \(r_{1}(t)=t^{4}\), \(r_{2}(t)=t^{2}\), \(p(t)=-(t-1)/(2t)\), \(g(t)=t-3\), \(h(t)=t\), and \(f(t,x)=tx^{3}+x/t^{2}\). It is obvious that the coefficients of (4.1) satisfy (C1)–(C4). Since

and

we obtain

and

By Theorem 3.1, we see that (4.1) has an eventually positive solution x satisfying \(\lim_{t\rightarrow \infty }x(t)=0\), where \(r_{2}z^{\Delta }\) and \(r_{1} (r_{2}z^{\Delta } )^{\Delta }\) are both eventually negative.

Now, we give the second example to demonstrate Theorems 3.2 and 3.3.

Example 4.2

Let \(\mathbb{T}=\bigcup_{n=1}^{\infty }[2^{n}-1,2^{n}]\). For \(t\in [3,\infty )_{\mathbb{T}}\), consider

Here, \(r_{1}(t)=t^{3}\), \(r_{2}(t)=t\), \(p(t)=1/2+1/t\), \(g(t)=t\), \(h(t)=t/2\), and \(f(t,x)=x/t^{2}\). It is obvious that the coefficients of (4.2) satisfy (C1)–(C4). Since

in terms of Theorem 3.2, we deduce that (4.2) has no eventually positive solutions x satisfying \(\lim_{t\rightarrow \infty }x(t)=0\), where \(r_{2}z^{\Delta }\) and \(r_{1} (r_{2}z^{\Delta } )^{\Delta }\) are both eventually negative. However, we have

and

Furthermore, there exists a constant \(M>0\) such that

and

By virtue of Theorem 3.3, we conclude that (4.2) has an eventually positive solution x satisfying \(\lim_{t\rightarrow \infty }x(t)=0\), where \(r_{2}z^{\Delta }\) is eventually negative and \(r_{1} (r_{2}z^{\Delta } )^{\Delta }\) is eventually positive.

Acknowledgements

The authors express their sincere gratitude to the editors for the careful reading of the original manuscript and useful comments that helped to improve the presentation of the results and accentuate important details.

Availability of data and materials

Data sharing not applicable to this article as no datasets were generated or analysed during the current study.

The research of the first author was supported by the National Natural Science Foundation of P. R. China (Grant No. 11671406) and Natural Science Program for Young Creative Talents of Innovation Enhancing College Project of Department of Education of Guangdong Province (Grant Nos. 2017GKQNCX111 and 2018-KJZX039). The research of the second author was supported by the Slovak Research and Development Agency (Grant No. APVV-18-0373). The research of the third author was supported by FGI 10-18 DIUMCE and PGI 03-2020 DIUMCE. The research of the fourth author was supported by the National Natural Science Foundation of P. R. China (Grant No. 61503171), China Postdoctoral Science Foundation (Grant No. 2015M582091), and Natural Science Foundation of Shandong Province (Grant No. ZR2016JL021).

Authors and Affiliations

1. School of Humanities, Shunde Polytechnic, Foshan, P.R. China

   Yang-Cong Qiu

2. Department of Mathematics and Theoretical Informatics, Faculty of Electrical Engineering and Informatics, Technical University of Košice, Košice, Slovakia

   Irena Jadlovská

3. Departamento de Matemática, Facultad de Ciencias Básicas, Universidad Metropolitana de Ciencias de la Educación, Santiago, Chile

   Kuo-Shou Chiu

4. School of Control Science and Engineering, Shandong University, Jinan, P.R. China

   Tongxing Li

5. LinDa Institute of Shandong Provincial Key Laboratory of Network Based Intelligent Computing, Linyi University, Linyi, P.R. China

   Tongxing Li

Contributions

All four authors contributed equally to this work. They all read and approved the final version of the manuscript.

Corresponding author

Correspondence to Tongxing Li.

Competing interests

The authors declare that they have no competing interests.

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

Reprints and permissions