Solvability of Iterative Classes of Nonlinear Elliptic Equations on an Exterior Domain

Wang, Xiaoming; Alzabut, Jehad; Khuddush, Mahammad; Fečkan, Michal

doi:10.3390/axioms12050474

Open AccessArticle

Solvability of Iterative Classes of Nonlinear Elliptic Equations on an Exterior Domain

¹

School of Mathematics and Computer Science, Shangrao Normal University, Shangrao 334001, China

²

Department of Mathematics and Sciences, Prince Sultan University, Riyadh 11586, Saudi Arabia

³

Department of Industrial Engineering, OSTİM Technical University, Ankara 06374, Türkiye

⁴

Department of Mathematics, Dr. Lankapalli Bullayya College of Engineering, Visakhapatnam 530013, Andhra Pradesh, India

⁵

Department of Mathematical Analysis and Numerical Mathematics, Faculty of Mathematics, Physics and Informatics, Comenius University in Bratislava, Mlynská Dolina, 842 48 Bratislava, Slovakia

⁶

Mathematical Institute, Slovak Academy of Sciences, Štefánikova 49, 814 73 Bratislava, Slovakia

^*

Author to whom correspondence should be addressed.

Axioms 2023, 12(5), 474; https://doi.org/10.3390/axioms12050474

Submission received: 25 March 2023 / Revised: 8 May 2023 / Accepted: 10 May 2023 / Published: 14 May 2023

(This article belongs to the Special Issue Special Topics in Differential Equations with Applications)

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Abstract

:

This work explores the possibility that iterative classes of elliptic equations have both single and coupled positive radial solutions. Our approach is based on using the well-known Guo–Krasnoselskii and Avery–Henderson fixed-point theorems in a Banach space. Furthermore, we utilize Rus’ theorem in a metric space, to prove the uniqueness of solutions for the problem. Examples are constructed for the sake of verification.

Keywords:

iterative class; elliptic equations; exterior domain; radial solutions; Banach space; complete metric space; fixed-point theorem

MSC:

35J66; 35J60; 34B18; 47H10

1. Introduction

The study of nonlinear elliptic systems has a strong motivation, and important research efforts have been made undertaken recently for these systems, aiming to apply the results of the existence and asymptotic behavior of positive solutions in applied fields (see [1,2,3,4,5]). The investigation of the following system of nonlinear elliptic equations in a bounded domain

℧ \subset R^{N}

,

▵ z_{_{β}} + λ F_{β} (z_{_{β + 1}}) = 0,

(1)

where

z_{_{β}} = 0

on

\partial ℧

and

z_{_{1}} = z_{_{d + 1}},

β \in {1, 2, 3, \dots, d},

has an important application in science and technology [6,7]. In [8], Dalmasso discussed the existence of positive solutions to such systems for

d = 2

when the

F_{} {(0)}^{'} s

are non-negative with at least one

F_{} (0) > 0

(positone problems). In [7], when

d = 2,

Ali–Ramaswamy–Shivaji discussed the existence of multiple positive solutions to such positone problems. In particular, in cases where one of

\frac{z}{F_{1} (z)}

or

\frac{z}{F_{2} (z)}

decreases for some range of

z,

they established conditions for the existence of at least three positive solutions for a certain range of

λ .

In [9], Hai–Shivaji discussed the existence of positive solutions for

λ > > 1

for cases where no sign conditions are assumed on

F_{} (0),

β \in {1, 2}

(semipositone problems). In [10], again for

d = 2,

Ali–Shivaji discussed the existence of multiple positive solutions for

λ > > 1

when

F_{} (0) = 0 = F_{}^{'} (0)

for

β \in {1, 2} .

In addition, in [11,12,13,14,15,16,17,18,19,20], relevant references to the most recent works on (1) can be found. Next, we quote some recent works on elliptic equations.

In [21], Padhi et al. derived sufficient conditions to the following problem in an annular domain:

\begin{matrix} ▵ z = λ F (| ν |, z), & z \in ℧ = {ν \in R^{N} : a_{1} < | ν | < a_{2}}, \\ z = 0, z \in \partial ℧, \end{matrix}

for the existence of positive radial solutions, by utilizing Gustafson and Schmitt fixed-point theorems. In [22], Chrouda and Hassine established the uniqueness of positive radial solutions to the following Dirichlet boundary value problem for the semilinear elliptic equation in an annulus:

\begin{matrix} ▵ z = F (z), & z \in ℧ = {ν \in R^{N} : a_{1} < | ν | < a_{2}}, \\ z = 0, z \in z \in \partial ℧, \end{matrix}

for any dimension

N \geq 1 .

In [23], Dong and Wei established the existence of radial solutions for the following nonlinear elliptic equations with gradient terms in annular domains:

\begin{matrix} ▵ z + g (| ν |, z, \frac{ν}{| ν |} \cdot \nabla z) = 0 in Ω_{a}^{b}, \\ z = 0 on \partial Ω_{a}^{b}, \end{matrix}

by using Schauder’s fixed-point theorem and contraction mapping theorem. In [24], R. Kajikiya and E. Ko established the existence of positive radial solutions for a semipositone elliptic equation of the form

\begin{matrix} ▵ z + λ g (z) = 0 in Ω, \\ z = 0 on \partial Ω, \end{matrix}

where

Ω

is a ball or an annulus in

R^{N} .

Recently, Son and Wang [25] considered the following system in an exterior ball

℧_{X}

:

\begin{matrix} ▵ z_{_{β}} + λ K_{β} (| ν |) F_{β} (z_{_{β + 1}}) = 0, \\ z_{_{β}} \to 0 as | ν | \to + \infty \\ z_{_{β}} = 0 on | ν | = r_{0}, \end{matrix}

where

β \in {1, 2, 3, \dots, d},

z_{_{1}} = z_{_{d + 1}},

and derived sufficient conditions for the existence of positive radial solutions. The above-mentioned works motivated us to study the following iterative classes of nonlinear elliptic equations on an exterior domain:

\begin{matrix} ▵ z_{_{β}} - \frac{{(N - 2)}^{2} r_{0}^{2 N - 2}}{{| ν |}^{2 N - 2}} z_{_{β}} + ϱ (| ν |) F_{β} (z_{_{β + 1}}) = 0, ν \in ℧, \\ lim_{| ν | \to \infty} z_{_{β}} (ν) = 0, z_{_{β}} |_{\partial ℧} = 0, \end{matrix}\}

(2)

where

β \in {1, 2, 3, \dots, n},

z_{_{1}} = z_{n + 1},

Δ z = div (\nabla z),

N > 2,

℧ = {z \in R^{N} | | z | > r_{0}},

ϱ = \prod_{i = 1}^{κ} ϱ_{i},

each

ϱ_{i} \in C ((r_{0}, + \infty), (0, + \infty)),

r^{N - 1} ϱ

is integrable. The Guo–Krasnoselskii cone fixed-point theorem is a key tool for obtaining single positive radial solutions, whereas the Avery–Henderson cone fixed-point theorem is utilized to obtain the coupled solutions. We further study the uniqueness of solutions of the problem (2) via Rus’ theorem in a metric space.

The study of the positive solutions to the iterative classes of ordinary differential equations with two-point boundary conditions,

\begin{matrix} z_{_{β}}^{″} (\hat{r}) - r_{0}^{2} z_{_{β}} (\hat{r}) + ϱ (\hat{r}) F_{β} (z_{_{β + 1}} (\hat{r})) = 0, 0 < \hat{r} < 1, \\ z_{_{β}} (0) = 0, z_{_{β}} (1) = 0, \end{matrix}\}

(3)

where

β \in {1, 2, 3, \dots, d},

z_{_{1}} = z_{_{d + 1}},

r_{0} > 0

and

ϱ (\hat{r}) = \frac{r_{0}^{2}}{{(N - 2)}^{2}} {\hat{r}}^{\frac{2 (N - 1)}{2 - N}} \prod_{i = 1}^{κ} ϱ_{i} (\hat{r}),

ϱ_{i} (\hat{r}) = ϱ_{i} (r_{0} {\hat{r}}^{\frac{1}{2 - N}})

by a Kelvin-type transformation [26,27] through the change of variables

m = | ν |

and

\hat{r} = {(\frac{m}{r_{0}})}^{2 - N},

facilitates the investigation of the positive radial solutions of (2).

We impose the below-mentioned presumptions whenever necessary:

$(J_{1})$: $F_{β} : [0, + \infty) \to [0, + \infty)$ is continuous.
$(J_{2})$: For $1 \leq \dot{ι} \leq d,$ $ϱ_{\dot{ι}} \in L^{p_{\dot{ι}}} [0, 1] (1 \leq p_{\dot{ι}} \leq + \infty)$ and $\exists ϱ_{\dot{ι}}^{★} > 0 ∋ ϱ_{\dot{ι}}^{★} < ϱ_{\dot{ι}} (\hat{r}) < \infty$ almost everywhere on the interval $[0, 1] .$

The remainder of the paper is structured as follows: The problem (3) is transformed into an analogous integral equation involving the kernel in Section 2. Additionally, we calculate the kernel boundaries that are crucial to our major findings. In Section 3, we employ Guo–Krasnoselskii’s cone fixed-point theorem, to provide a criterion for the single positive radial solution. In Section 4, the coupled solutions are established by the Avery–Henderson cone fixed-point theorem. The final portion deals with a unique solution. Meanwhile, some numerical examples are provided.

2. Preliminaries

The essential results are stated here, prior to proceeding to the main results in the subsequent sections.

Lemma 1.

For every

℘ \in C [0, 1],

the BVP

- z_{_{1}}^{″} (\hat{r}) + r_{0}^{2} z_{_{1}} (\hat{r}) = ℘ (\hat{r}), 0 < \hat{r} < 1,

z_{_{1}} (0) = z_{_{1}} (1) = 0,

has a unique solution

z_{_{1}} (\hat{r}) = \int_{0}^{1} Q (\hat{r}, ζ) ℘ (ζ) d ζ,

where

\begin{matrix} Q (\hat{r}, ζ) = \frac{1}{r_{0} sinh (r_{0})} \{\begin{matrix} sinh (r_{0} \hat{r}) sinh (r_{0} (1 - ζ)), 0 \leq \hat{r} \leq ζ \leq 1, \\ sinh (r_{0} ζ) sinh (r_{0} (1 - \hat{r})), 0 \leq ζ \leq \hat{r} \leq 1 . \end{matrix} \end{matrix}

Lemma 2.

The kernel

Q (\hat{r}, ζ)

has the subsequent characteristics:

(i): $Q (\hat{r}, ζ) \geq 0$ and continuous on $[0, 1] \times [0, 1];$
(ii): $Q (\hat{r}, ζ) \leq Q (ζ, ζ),$ $\hat{r}, ζ \in [0, 1];$
(iii): there exists $ξ \in (0, \frac{1}{2})$ such that $σ (ξ) Q (ζ, ζ) \leq Q (\hat{r}, ζ),$ $(\hat{r}, ζ) \in [ξ, 1 - ξ] \times [0, 1],$ where $σ (ξ) = \frac{sinh (r_{0} ξ)}{sinh (r_{0})} .$

Proof.

(i) is evident. The following proves (ii):

\begin{matrix} \frac{Q (\hat{r}, ζ)}{Q (ζ, ζ)} = & \{\begin{matrix} \frac{sinh (r_{0} \hat{r})}{sinh (r_{0} ζ)}, 0 \leq \hat{r} \leq ζ \leq 1, \\ \frac{sinh (r_{0} (1 - \hat{r}))}{sinh (r_{0} (1 - ζ))}, 0 \leq ζ \leq \hat{r} \leq 1, \end{matrix} \\ \leq & \{\begin{matrix} 1, 0 \leq \hat{r} \leq ζ \leq 1, \\ 1, 0 \leq ζ \leq \hat{r} \leq 1, \end{matrix} \end{matrix}

For (iii), we consider

\begin{matrix} \frac{Q (\hat{r}, ζ)}{Q (ζ, ζ)} = & \{\begin{matrix} \frac{sinh (r_{0} \hat{r})}{sinh (r_{0} ζ)}, 0 \leq \hat{r} \leq ζ \leq 1, \\ \frac{sinh (r_{0} (1 - \hat{r}))}{sinh (r_{0} (1 - ζ))}, 0 \leq ζ \leq \hat{r} \leq 1, \end{matrix} \\ \geq & \{\begin{matrix} \frac{sinh (r_{0} ξ)}{sinh (r_{0})}, 0 \leq \hat{r} \leq ζ \leq 1, ξ \leq \hat{r} \leq 1 - ξ, \\ \frac{sinh (r_{0} ξ)}{sinh (r_{0})}, 0 \leq ζ \leq \hat{r} \leq 1, ξ \leq \hat{r} \leq 1 - ξ, \end{matrix} \\ = & σ . \end{matrix}

The proof is now completed. □

We observe that a

d

-tuple

(z_{_{1}}, z_{2}, \dots, z_{d})

is a solution of BVP (3) from Lemma 1 if and only if

\begin{matrix} z_{_{1}} (\hat{r}) = & \int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1} . \end{matrix}

In general,

\begin{matrix} z_{_{β}} (\hat{r}) = & \int_{0}^{1} Q (\hat{r}, ζ) ϱ (ζ) F_{β} (z_{_{β + 1}} (ζ)) d ζ, β = 1, 2, 3, \dots, d, \\ z_{_{1}} (\hat{r}) = & z_{_{d + 1}} (\hat{r}) . \end{matrix}

Let

ℵ : = C ((0, 1), R)

be a Banach space equipped with a norm

∥ z ∥ = max_{\hat{r} \in [0, 1]} | z (\hat{r}) |

, and

X_{ξ} = \{z \in ℵ : z (\hat{r}) \geq 0 on [0, 1], min_{\hat{r} \in [ξ, 1 - ξ]} z (\hat{r}) \geq σ (ξ) ∥ z ∥\}

be a cone, for

ξ \in (0, \frac{1}{2}) .

For any

z_{_{1}} \in X,

define an operator

£ : X \to ℵ

by

\begin{matrix} (£ z_{_{1}}) (\hat{r}) = & \int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1} . \end{matrix}

(4)

Lemma 3.

£ is self–mapping on

X_{ξ}

and

£ : X_{ξ} \to X_{ξ}

is completely continuous.

Proof.

As

F_{β} (z_{_{β + 1}} (\hat{r})) \geq 0

and

Q (\hat{r}, ζ) \geq 0

for

\hat{r}, ζ \in [0, 1],

we have

£ (z_{_{1}} (\hat{r})) \geq 0

for

\hat{r} \in [0, 1], z_{_{1}} \in X_{ξ} .

Applying Lemmas 1 and 2, we obtain

\begin{matrix} min_{\hat{r} \in [ξ, 1 - ξ]} (£ z_{_{1}}) (\hat{r}) & = min_{\hat{r} \in [ξ, 1 - ξ]} {\int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1}} \\ \geq σ (ξ) {\int_{0}^{1} Q (ζ_{1}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1}} \\ \geq σ (ξ) {\int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1}} \\ \geq σ (ξ) max_{\hat{r} \in [0, 1]} | £ z_{_{1}} (\hat{r}) | . \end{matrix}

Thus,

£ (X_{ξ}) \subset X_{ξ} .

In light of this, the operator £ is fully continuous according to the Arzela–Ascoli theorem. □

The following theorems are key tools for the existence of positive solutions:

Theorem 1 (Hölder’s [28]).

For

ℓ = 1, 2, \dots, κ,

and

p_{ℓ} > 1,

let

ℏ \in L^{p_{ℓ}} [0, 1]

with

\sum_{ℓ = 1}^{κ} \frac{1}{p_{ℓ}} = 1;

then,

\prod_{ℓ = 1}^{κ} ℏ_{ℓ} \in L^{1} [0, 1]

and

{∥\prod_{ℓ = 1}^{κ} ℏ_{ℓ}∥}_{1} \leq \prod_{ℓ = 1}^{κ} {∥ ℏ_{ℓ} ∥}_{p_{ℓ}} .

Furthermore, if

ℏ \in L^{1} [0, 1]

and

\bar{g} \in L^{\infty} [0, 1]

then

ℏ \bar{g} \in L^{1} [0, 1]

and

∥ ℏ \bar{g} ∥_{1} \leq {∥ ℏ ∥}_{1} {∥ \bar{g} ∥}_{\infty} .

Theorem 2 (Guo–Krasnoselskii [29]).

Let

G

be a Banach space, and let

N_{1}, N_{2}

be bounded open subsets of

G

with

0 \in N_{1} \subset {\bar{N}}_{1} \subset N_{2}

and

ℵ : X \cap ({\bar{N}}_{2} \ N_{1}) \to X

(X \subset G

is a cone) as a completely continuous operator, such that

(i): $∥ ℵ z ∥ \leq ∥ z ∥, z \in X \cap \partial N_{1},$ and $∥ ℵ z ∥ \geq ∥ z ∥, z \in X \cap \partial N_{2},$ or
(ii): $∥ ℵ z ∥ \geq ∥ z ∥, z \in X \cap \partial N_{1},$ and $∥ ℵ z ∥ \leq ∥ z ∥, z \in X \cap \partial N_{2};$

then, ℵ has a fixed point in

X \cap ({\bar{N}}_{2} \ N_{1}) .

Let

ψ \geq 0

be a continuous functional on a cone

X

, and let

f > 0

and

h > 0 .

Define

X (ψ, h) = {z \in X : ψ (z) < h}

and

X_{f} = {z \in X : ∥ z ∥ < f} .

Theorem 3 (Avery–Henderson [30]).

If

γ_{1} \geq 0,

γ_{2} \geq 0,

γ_{3} \geq 0

continuous and increasing functionals on

X,

γ_{3} (0) = 0

, such that, for some positive numbers

h

and

k,

γ_{2} (z) \leq γ_{3} (z) \leq γ_{1} (z)

and

∥ z ∥ \leq k γ_{2} (z),

for all

z \in \bar{X (γ_{2}, h)},

and there exist

f > 0

and

g > 0

with

f < g < h

, such that

γ_{3} (λ z) \leq λ γ_{3} (z),

for

0 \leq λ \leq 1

and

z \in \partial X (γ_{3}, g) .

Furthermore, if

£ : \bar{X (γ_{2}, h)} \to X

is a completely continuous operator, such that

$(a)$: $γ_{2} (£ z) > h,$ for all $z \in \partial X (γ_{2}, h),$
$(b)$: $γ_{3} (£ z) < g,$ for all $z \in \partial X (γ_{3}, g),$
$(c)$: $X (γ_{1}, f) \neq Ø$ and $γ_{1} (£ z) > f,$ for all $\partial X (γ_{1}, f),$

then £ has at least two fixed points

^{1} z,^{2} z \in P (γ_{2}, h)

, such that

f < γ_{1} (^{1} z)

with

γ_{3} (^{1} z) < g

and

g < γ_{3} (^{2} z)

with

γ_{2} (^{2} z) < h .

Define the non-negative, increasing, continuous functional

γ_{2}, γ_{3},

and

γ_{1}

by

\begin{matrix} γ_{2} (z) = min_{\hat{r} \in [ξ, 1 - ξ]} z (\hat{r}), γ_{3} (z) = max_{\hat{r} \in [0, 1]} z (\hat{r}), γ_{1} (z) = max_{\hat{r} \in [0, 1]} z (\hat{r}) . \end{matrix}

It is obvious that for each

z \in X,

γ_{2} (z) \leq γ_{3} (z) = γ_{1} (z),

and

γ_{2} (z) \geq σ (ξ) ∥ z ∥ .

Thus,

∥ z ∥ \leq \frac{1}{σ (ξ)} γ_{2} (z)

for all

z \in X .

Furthermore, we observe that

γ_{3} (λ z) = λ γ_{3} (z),

for

0 \leq λ \leq 1,

z \in X .

3. Single Positive Radial Solution

In accordance with Guo–Krasnoselskii’s theorem, we demonstrate in this section that problem (3) has a single positive radial solution.

For

ϱ_{i} \in L^{p_{i}} [0, 1],

we have the following cases:

\sum_{i = 1}^{κ} \frac{1}{p_{i}} < 1, \sum_{i = 1}^{κ} \frac{1}{p_{i}} = 1, \sum_{i = 1}^{κ} \frac{1}{p_{i}} > 1 .

We discuss the positive radial solutions for

\sum_{i = 1}^{κ} \frac{1}{p_{i}} < 1,

in the following theorem:

Theorem 4.

Suppose that

(J_{1})

–

(J_{2})

hold, and there exist positive constants

a_{2} > a_{1} > 0

, such that

$(J_{3})$: $F_{β} (z (\hat{r})) \leq R_{2} a_{2}$ for $0 \leq \hat{r} \leq 1, 0 \leq z \leq a_{2},$ where $R_{2} = {[\frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{q} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}}]}^{- 1}$ and $\hat{Q} (ζ) = Q (ζ, ζ) ζ^{\frac{2 (N - 1)}{2 - N}},$
$(J_{4})$: $F_{β} (z (\hat{r})) \geq R_{1} a_{1}$ for $ξ \leq \hat{r} \leq 1 - ξ, σ (ξ) a_{1} \leq z \leq a_{1},$ where

$R_{1} = {[\frac{σ (ξ) r_{0}^{2}}{{(N - 2)}^{2}} \prod_{i = 1}^{κ} ϱ_{i}^{★} \int_{ξ}^{1 - ξ} Q (ζ, ζ) ζ^{\frac{2 (N - 1)}{2 - N}} d ζ]}^{- 1},$

then the BVP (3) has a solution

(z_{_{1}}, z_{2}, \dots, z_{d})

, such that

z_{_{β}} > 0, a_{1} \leq ∥ z_{_{β}} ∥ \leq a_{2}, β = 1, 2, \dots, d .

Proof.

Let

N_{1} = {z \in ℵ : ∥ z ∥ < a_{1}}

and

N_{2} = {z \in ℵ : ∥ z ∥ < a_{2}} .

For

z_{_{1}} \in \partial N_{2},

0 \leq z_{1} \leq a_{2}

for

\hat{r} \in [0, 1] .

For

ζ_{d - 1} \in [0, 1],

and from

(J_{3}),

we obtain

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} & \leq \int_{0}^{1} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} \\ \leq R_{2} a_{2} \int_{0}^{1} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) d ζ_{d} \\ \leq R_{2} a_{2} \frac{r_{0}^{2}}{{(N - 2)}^{2}} \int_{0}^{1} Q (ζ_{d}, ζ_{d}) ζ_{d}^{\frac{2 (N - 1)}{2 - N}} \prod_{i = 1}^{κ} ϱ_{i} (ζ_{d}) d ζ_{d} . \end{matrix}

Now, there exists

q > 1

, such that

\sum_{i = 1}^{κ} \frac{1}{p_{i}} + \frac{1}{q} = 1 .

From Theorem 1, we have

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} & \leq R_{2} a_{2} \frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{q} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}} \\ \leq a_{2} . \end{matrix}

Similarly, for

0 < ζ_{d - 2} < 1,

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 2}, ζ_{d - 1}) ϱ (ζ_{d - 1}) F_{d - 1} & [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] d ζ_{d - 1} \\ \leq \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d - 1}) ϱ (ζ_{d - 1}) F_{d - 1} (a_{2}) d ζ_{d - 1} \\ \leq R_{2} a_{2} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d - 1}) ϱ (ζ_{d - 1}) d ζ_{d - 1} \\ \leq R_{2} a_{2} \frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{q} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}} \\ \leq a_{2} . \end{matrix}

Following this bootstrapping reasoning, we arrive at

\begin{matrix} (£ z_{_{1}}) (t) = & \int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1} \\ \leq & a_{2} . \end{matrix}

As

N_{2} = ∥ z_{_{1}} ∥

for

z_{_{1}} \in X \cap \partial N_{2},

we obtain

∥ £ z_{_{1}} ∥ \leq ∥ z_{_{1}} ∥ .

(5)

Let

\hat{r} \in [ξ, 1 - ξ];

then,

a_{1} = ∥ z_{_{1}} ∥ \geq z_{_{1}} (\hat{r}) \geq min_{\hat{r} \in [ξ, 1 - ξ]} z_{_{1}} (t) \geq σ (ξ) ∥ z_{_{1}} ∥ \geq σ (ξ) a_{1} .

By

(J_{4})

and for

ζ_{d - 1} \in [ξ, 1 - ξ],

we have

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} & \geq \int_{ξ}^{1 - ξ} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} \\ \geq σ (ξ) \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} \\ \geq σ (ξ) R_{1} a_{1} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) d ζ_{d} \\ \geq R_{1} a_{1} \frac{σ (ξ) r_{0}^{2}}{{(N - 2)}^{2}} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ζ_{d}^{\frac{2 (N - 1)}{2 - d}} \prod_{i = 1}^{κ} ϱ_{i} (ζ_{d}) d ζ_{d} \\ \geq R_{1} a_{1} \frac{σ (ξ) r_{0}^{2}}{{(N - 2)}^{2}} \prod_{i = 1}^{κ} ϱ_{i}^{★} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ζ_{d}^{\frac{2 (N - 1)}{2 - N}} d ζ_{d} \\ \geq a_{1} . \end{matrix}

Similarly, for

0 < ζ_{d - 2} < 1,

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 2}, ζ_{d - 1}) ϱ (ζ_{d - 1}) F_{d - 1} & [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] d ζ_{d - 1} \\ \geq \int_{ξ}^{1 - ξ} Q (ζ_{d - 2}, ζ_{d - 1}) ϱ (ζ_{d - 1}) F_{d - 1} (a_{1}) d ζ_{d - 1} \\ \geq σ (ξ) \int_{ξ}^{1 - ξ} Q (ζ_{d - 1}, ζ_{d - 1}) ϱ (ζ_{d - 1}) F_{d - 1} (a_{1}) d ζ_{d - 1} \\ \geq σ (ξ) R_{1} a_{1} \int_{ξ}^{1 - ξ} Q (ζ_{d - 1}, ζ_{d - 1}) ϱ (ζ_{d - 1}) d ζ_{d - 1} \\ \geq R_{1} a_{1} \frac{σ (ξ) r_{0}^{2}}{{(N - 2)}^{2}} \int_{ξ}^{1 - ξ} Q (ζ_{d - 1}, ζ_{d - 1}) ζ_{d - 1}^{\frac{2 (N - 1)}{2 - d}} \prod_{i = 1}^{κ} ϱ_{i} (ζ_{d - 1}) d ζ_{d - 1} \\ \geq R_{1} a_{1} \frac{σ (ξ) r_{0}^{2}}{{(N - 2)}^{2}} \prod_{i = 1}^{κ} ϱ_{i}^{★} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d - 1}) ζ_{d - 1}^{\frac{2 (N - 1)}{2 - N}} d ζ_{d - 1} \\ \geq a_{1} . \end{matrix}

It follows that

\begin{matrix} (£ z_{_{1}}) (\hat{r}) = & \int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1} \\ \geq & a_{1} . \end{matrix}

Thus, for

z_{_{1}} \in X \cap \partial N_{1},

we have

∥ £ z_{_{1}} ∥ \geq ∥ z_{_{1}} ∥ .

(6)

It can be seen that

0 \in N_{1} \subset {\bar{N}}_{1} \subset N_{2}

, and from (5), (6), and Theorem 2, the operator £ has a fixed point

z_{_{1}} \in X \cap ({\bar{N}}_{2} \ N_{1})

and

z_{_{1}} (\hat{r}) \geq 0

on

(0, 1) .

Now, put

z_{_{1}} = z_{_{d + 1}},

to obtain an infinite number of solutions:

\begin{matrix} z_{_{β}} (\hat{r}) & = \int_{0}^{1} Q (\hat{r}, s) ϱ (s) F_{β} (z_{_{β + 1}} (s)) d s, β = 1, 2, \dots, d - 1, d, \\ z_{_{d + 1}} (\hat{r}) & = z_{_{1}} (\hat{r}), \hat{r} \in (0, 1) . \end{matrix}

□

For the cases

\sum_{i = 1}^{κ} \frac{1}{p_{i}} = 1

and

\sum_{i = 1}^{κ} \frac{1}{p_{i}} > 1,

we have the following theorems:

Theorem 5.

Suppose

(J_{1})

–

(J_{2})

hold, and there exist constants

b_{2} > b_{1} > 0

with

F_{β} (β = 1, 2, \dots, d)

satisfies

(J_{4})

and

$(J_{5})$: $F_{β} (z (\hat{r})) \leq N_{2} b_{2}$ for $0 \leq \hat{r} \leq 1, 0 \leq z \leq b_{2},$ where $N_{2} = {[\frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{\infty} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}}]}^{- 1}$ and $\hat{Q} (ζ) = Q (ζ, ζ) ζ^{\frac{2 (N - 1)}{2 - N}};$

then the BVP (3) has a solution

(z_{_{1}}, z_{2}, \dots, z_{d})

, such that

z_{_{β}} > 0, b_{1} \leq ∥ z_{_{β}} ∥ \leq b_{2}, β = 1, 2, \dots, d .

Proof.

The proof is similar to the proof of Theorem 4; therefore, we omit the details here. □

Theorem 6.

Suppose

(J_{1})

–

(J_{2})

hold, and there exist constants

c_{2} > c_{1} > 0

with

F_{β} (β = 1, 2, \dots, d)

satisfying

(J_{4})

and

$(J_{6})$: $F_{β} (z (\hat{r})) \leq M_{2} c_{2}$ for all $0 \leq \hat{r} \leq 1, 0 \leq z \leq c_{2},$ where $M_{2} = {[\frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{\infty} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{1}]}^{- 1}$ and $\hat{Q} (ζ) = Q (ζ, ζ) ζ^{\frac{2 (N - 1)}{2 - N}},$

then the BVP (3) has a solution

(z_{_{1}}, z_{2}, \dots, z_{d})

, such that

z_{_{β}} > 0, c_{1} \leq ∥ z_{_{β}} ∥ \leq c_{2}, β = 1, 2, \dots, d .

Proof.

The proof is similar to the proof of Theorem 4; therefore, we omit the details here. □

Example 1.

Consider the problem

▵ z_{_{β}} - \frac{{(N - 2)}^{2} r_{0}^{2 N - 2}}{{| ν |}^{2 N - 2}} z_{_{β}} + ϱ (| ν |) F_{β} (z_{_{β + 1}}) = 0, 1 < | ν | < 3,

(7)

z_{_{β}} (0) = 0, z_{_{β}} (1) = 0,

(8)

where

r_{0} = 1,

N = 3,

β \in {1, 2}, z_{3} = z_{_{1}},

ϱ (\hat{r}) = \frac{1}{{\hat{r}}^{4}} \prod_{i = 1}^{2} ϱ_{i} (\hat{r}),

ϱ_{i} (\hat{r}) = ϱ_{i} (\frac{1}{\hat{r}}),

in which

ϱ_{1} (t) = \frac{2}{t^{2} + 1}

and

ϱ_{2} (t) = \frac{1}{\sqrt{t + 2}},

then

ϱ_{1}, ϱ_{2} \in L^{p} [0, 1]

and

\prod_{i = 1}^{2} ϱ_{i}^{*} = \frac{1}{\sqrt{3}} .

Let

ξ = \frac{1}{3},

F_{1} (z) = F_{2} (z) = 1 + \frac{1}{3} | sin (1 + z) | + \frac{1}{1 + z} .

\begin{matrix} Q (\hat{r}, ζ) = \frac{1}{sinh (1)} \{\begin{matrix} sinh (\hat{r}) sinh (1 - ζ), 0 \leq \hat{r} \leq ζ \leq 1, \\ sinh (ζ) sinh (1 - \hat{r}), 0 \leq ζ \leq \hat{r} \leq 1, \end{matrix} \end{matrix}

and

σ (ξ) = \frac{sinh (ξ)}{sinh (1)} = \frac{sinh (\frac{1}{3})}{sinh (1)} = 0.2889212153 .

In addition,

\begin{matrix} R_{1} = {[\frac{σ (ξ) r_{0}^{2}}{{(N - 2)}^{2}} \prod_{i = 1}^{κ} ϱ_{i}^{★} \int_{ξ}^{1 - ξ} Q (ζ, ζ) ζ^{\frac{2 (N - 1)}{2 - N}} d ζ]}^{- 1} \approx 2.932844681 . \end{matrix}

Let

p_{1} = 2, p_{2} = 3

and

q = 6,

then

\frac{1}{p_{1}} + \frac{1}{p_{2}} + \frac{1}{q} = 1

and

\begin{matrix} R_{2} = {[\frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{q} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}}]}^{- 1} \approx 4.284821634 . \end{matrix}

Choose

a_{1} = \frac{1}{2}

and

a_{2} = 1 .

Then,

\begin{matrix} F_{1} (z) = F_{2} (z) & = 1 + \frac{1}{3} | sin (1 + z) | + \frac{1}{1 + z} \leq 4.284821634 = R_{2} a_{2}, 0 \leq z \leq 1, \\ F_{1} (z) = F_{2} (z) & = 1 + \frac{1}{3} | sin (1 + z) | + \frac{1}{1 + z} \geq 1.466422340 = R_{1} a_{1}, 0.1444606076 \leq z \leq \frac{1}{2} . \end{matrix}

Thus, by Theorem 4, BVP (7) and (8) has at least one positive solution

(z_{_{1}}, z_{2})

, such that

\frac{1}{2} \leq ∥ z_{_{β}} ∥ \leq 1

for

β = 1, 2 .

4. Existence of Coupled Positive Radial Solutions

By utilizing the Avery–Henderson cone fixed-point theorem, we demonstrate in this section that there are coupled positive solutions for (3). Denote

β_{1} = \frac{σ (ξ) r_{0}^{2}}{{(N - 2)}^{2}} \prod_{i = 1}^{κ} ϱ_{i}^{★} \int_{0}^{1} Q (ζ, ζ) ζ^{\frac{2 (N - 1)}{2 - N}} d ζ,

β_{2} = \frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{q} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}},

β_{3} = \frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{\infty} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}},

β_{4} = \frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{\infty} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{1} .

Theorem 7.

Suppose that

(J_{1})

–

(J_{2})

hold, and that there exist three positive real numbers

f < g < h

with

F_{β} (β = 1, 2, \dots, d)

satisfying

$(J_{7})$: $F_{β} (z) > \frac{h}{β_{1}}$ , $h \leq z \leq \frac{h}{σ (ξ)},$
$(J_{8})$: $F_{β} (z) < \frac{g}{β_{2}}$ , $0 \leq z \leq \frac{g}{σ (ξ)},$
$(J_{9})$: $F_{β} (z) > \frac{f}{β_{1}}$ , $f \leq z \leq \frac{f}{σ (ξ)},$

then the BVP (3) has coupled positive solutions

{(^{1} z_{_{1}},^{1} z_{2}, \dots,^{1} z_{d})}

and

{(^{2} z_{_{1}},^{2} z_{2}, \dots,

^{2} z_{d})}

satisfying

f < γ_{1} (^{1} z_{_{β}}) with γ_{3} (^{1} z_{_{β}}) < g, β = 1, 2, \dots, d

and

g < γ_{3} (^{2} z_{_{β}}) with γ_{2} (^{2} z_{_{β}}) < h, β = 1, 2, \dots, d .

Proof.

It is easy to demonstrate that

£ : \bar{X (γ_{2}, h)} \to X

and £ are completely continuous from (4): first, we check that the condition

(a)

of Theorem 3 holds; for this, we choose

z_{_{1}} \in \partial X (γ_{2}, h);

then,

γ_{2} (z_{_{1}}) = {min}_{\hat{r} \in [ξ, 1 - ξ]} z_{_{1}} (\hat{r}) = h

, so

h \leq z_{_{1}} (\hat{r})

for

\hat{r} \in [ξ, 1 - ξ] .

As

∥ z_{_{1}} ∥ \leq \frac{1}{σ (ξ)} γ_{2} (z_{_{1}}) = \frac{1}{σ (ξ)} h,

we have

h \leq z_{_{1}} (\hat{r}) \leq \frac{h}{σ (ξ)}, \hat{r} \in [ξ, 1 - ξ] .

Let

ζ_{d - 1} \in [ξ, 1 - ξ] .

Then, by

(J_{7}),

we have

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} & \geq σ (ξ) \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} \\ \geq \frac{σ (ξ) h}{β_{1}} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) d ζ_{d} \\ \geq \frac{σ (ξ) h r_{0}^{2}}{{(N - 2)}^{2} β_{1}} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ζ_{d}^{\frac{2 (N - 1)}{2 - N}} \prod_{i = 1}^{κ} ϱ_{i} (ζ_{d}) d ζ_{d} \\ \geq \frac{σ (ξ) h r_{0}^{2}}{{(N - 2)}^{2} β_{1}} \prod_{i = 1}^{κ} ϱ_{i}^{★} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ζ_{d}^{\frac{2 (N - 1)}{2 - N}} d ζ_{d} \\ \geq h . \end{matrix}

Following this, we arrive at

\begin{matrix} γ_{2} (£ z_{_{1}}) = & min_{\hat{r} \in [0, 1]} \int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1} \\ \geq & h . \end{matrix}

Condition

(a)

of Theorem 3 is proved. To prove

(b),

choose

z_{_{1}} \in \partial X (γ_{3}, g) .

Then,

γ_{3} (z_{_{1}}) = {max}_{\hat{r} \in [0, 1]} z_{_{1}} (\hat{r}) = g

, so that

0 \leq z_{_{1}} (\hat{r}) \leq g

for

\hat{r} \in [0, 1] .

As

∥ z_{_{1}} ∥ \leq \frac{1}{σ (ξ)} γ_{2} (z_{_{1}}) \leq \frac{1}{σ (ξ)} γ_{3} (z_{_{1}}) = \frac{g}{σ (ξ)},

we have

0 \leq z_{_{1}} (\hat{r}) \leq σ {(ξ)}^{2} g, \hat{r} \in [0, 1] .

Let

0 < ζ_{d - 1} < 1 .

Then, by

(J_{8}),

we have

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} & \leq σ (ξ) \int_{0}^{1} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} \\ \leq \frac{σ (ξ) g}{β_{2}} \int_{0}^{1} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) d ζ_{d} \\ \leq \frac{σ (ξ) g r_{0}^{2}}{{(N - 2)}^{2} β_{2}} \int_{0}^{1} Q (ζ_{d}, ζ_{d}) ζ_{d}^{\frac{2 (N - 1)}{2 - N}} \prod_{i = 1}^{κ} ϱ_{i} (ζ_{d}) d ζ_{d} . \end{matrix}

For some

q > 1,

we have

\frac{1}{q} + \sum_{i = 1}^{κ} \frac{1}{p_{i}} = 1 .

From Theorem 1, we have

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} & \leq \frac{σ (ξ) g r_{0}^{2}}{{(N - 2)}^{2} β_{2}} ∥ \hat{Q} ∥_{q} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}} \leq g . \end{matrix}

It follows that

\begin{matrix} γ_{3} (£ z_{_{1}}) = & max_{\hat{r} \in [0, 1]} \int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1} \\ \leq & g . \end{matrix}

Thus,

(b)

holds. Finally, we also check that

(c)

of Theorem 3 holds. Observe that

z_{_{1}} (\hat{r}) = f / 4 \subset X (γ_{1}, f)

and

f / 4 < f,

so that

X (γ_{1}, f) \neq Ø .

Next, if

z_{_{1}} \in X (γ_{1}, f),

then

f = γ_{1} (z_{_{1}}) = {max}_{\hat{r} \in [0, 1]} z_{_{1}} (\hat{r}) = ∥ z_{_{1}} ∥ = \frac{1}{σ (ξ)} γ_{2} (z_{_{1}}) \leq \frac{1}{σ (ξ)} γ_{3} (z_{_{1}}) = \frac{1}{σ (ξ)} γ_{1} (z_{_{1}}) = \frac{f}{σ (ξ)},

i.e.,

f \leq z_{_{1}} (\hat{r}) \leq \frac{f}{σ (ξ)}

for

\hat{r} \in [0, 1] .

Let

0 < ζ_{d - 1} < 1 .

Then, by

(J_{9}),

we have

\begin{matrix} \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} & \geq σ (ξ) \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} \\ \geq \frac{σ (ξ) f}{β_{1}} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) d ζ_{d} \\ \geq \frac{σ (ξ) f r_{0}^{2}}{{(N - 2)}^{2} β_{1}} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ζ_{d}^{\frac{2 (N - 1)}{2 - N}} \prod_{i = 1}^{κ} ϱ_{i} (ζ_{d}) d ζ_{d} \\ \geq \frac{σ (ξ) f r_{0}^{2}}{{(N - 2)}^{2} β_{1}} \prod_{i = 1}^{κ} ϱ_{i}^{★} \int_{ξ}^{1 - ξ} Q (ζ_{d}, ζ_{d}) ζ_{d}^{\frac{2 (N - 1)}{2 - N}} d ζ_{d} \\ \geq f . \end{matrix}

Following this bootstrapping reasoning, we arrive at

\begin{matrix} γ_{1} (£ z_{_{1}}) = & max_{\hat{r} \in [0, 1]} \int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1} \\ \geq & min_{\hat{r} \in [0, 1]} \int_{0}^{1} Q (\hat{r}, ζ_{1}) ϱ (ζ_{1}) F_{1} [\int_{0}^{1} Q (ζ_{1}, ζ_{2}) ϱ (ζ_{2}) F_{2} [\int_{0}^{1} Q (ζ_{2}, ζ_{3}) ϱ (ζ_{3}) F_{4} \dots \\ F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] \dots] d ζ_{3}] d ζ_{2}] d ζ_{1} \\ \geq & f . \end{matrix}

Thus, assumption

(c)

of Theorem 3 holds. Hence, by Theorem 3, there exist coupled positive solutions as mentioned in the hypothesis. □

The following theorems are for the cases,

\sum_{i = 1}^{κ} \frac{1}{p_{i}} = 1

and

\sum_{i = 1}^{κ} \frac{1}{p_{i}} > 1,

respectively:

Theorem 8.

Suppose that

(J_{1})

–

(J_{2})

hold, and there exist three positive real numbers

f < g < h

with

F_{β} (β = 1, 2, \dots, d)

satisfying

(J_{7}),

(J_{9})

, and

$(J_{10})$: $F_{β} (z) < \frac{g}{β_{3}}$ , $0 \leq z \leq \frac{g}{σ (ξ)},$

then the BVP (3) has coupled positive solutions

{(^{1} z_{_{1}},^{1} z_{2}, \dots,^{1} z_{d})}

and

{(^{2} z_{_{1}},^{2} z_{2}, \dots,

^{2} z_{d})}

satisfying

f < γ_{1} (^{1} z_{_{β}}) with γ_{3} (^{1} z_{_{β}}) < g, β = 1, 2, \dots, d

and

g < γ_{3} (^{2} z_{_{β}}) with γ_{2} (^{2} z_{_{β}}) < h, β = 1, 2, \dots, d .

Proof.

The proof is similar to the proof of Theorem 7; therefore, we omit the details here. □

Theorem 9.

Suppose that

(J_{1})

–

(J_{3})

hold, and there exist three positive real numbers

0 < f < g < h

with

F_{β} (β = 1, 2, \dots, d)

satisfying

(J_{7}),

(J_{9})

and

$(J_{11})$: $F_{β} (z) < \frac{g}{β_{4}}$ , $0 \leq z \leq \frac{g}{σ (ξ)},$

then the BVP (3) has coupled positive solutions

{(^{1} z_{_{1}},^{1} z_{2}, \dots,^{1} z_{d})}

and

{(^{2} z_{_{1}},^{2} z_{2}, \dots,

^{2} z_{d})}

satisfying

f < γ_{1} (^{1} z_{_{β}}) with γ_{3} (^{1} z_{_{β}}) < g, β = 1, 2, \dots, d

and

g < γ_{3} (^{2} z_{_{β}}) with γ_{2} (^{2} z_{_{β}}) < h, β = 1, 2, \dots, d .

Proof.

The proof is similar to the proof of Theorem 7; therefore, we omit the details here. □

Example 2.

Consider the problem

▵ z_{_{β}} - \frac{{(N - 2)}^{2} r_{0}^{2 N - 2}}{{| ν |}^{2 N - 2}} z_{_{β}} + ϱ (| ν |) F_{β} (z_{_{β + 1}}) = 0, 1 < | ν | < 3,

(9)

z_{_{β}} (0) = z_{_{β}} (1) = 0,

(10)

where

r_{0} = 1,

N = 3,

β \in {1, 2}, z_{_{3}} = z_{_{1}},

ϱ (\hat{r}) = \frac{1}{{\hat{r}}^{4}} \prod_{i = 1}^{2} ϱ_{i} (\hat{r}),

ϱ_{i} (\hat{r}) = ϱ_{i} (\frac{1}{\hat{r}}),

in which

ϱ_{1} (\hat{r}) = \frac{1}{\hat{r} + 2}

and

ϱ_{2} (\hat{r}) = \frac{3}{{\hat{r}}^{2} + 1},

then

ϱ_{1}, ϱ_{2} \in L^{p} [0, 1], \prod_{i = 1}^{2} ϱ_{i}^{*} = \frac{1}{2},

and

σ (ξ) = \frac{sinh (ξ)}{sinh (1)} = \frac{sinh (\frac{1}{3})}{sinh (1)} = 0.2889212153 .

In addition,

\begin{matrix} β_{1} = \frac{σ (ξ) r_{0}^{2}}{{(N - 2)}^{2}} \prod_{i = 1}^{κ} ϱ_{i}^{★} \int_{ξ}^{1 - ξ} Q (ζ, ζ) ζ^{\frac{2 (N - 1)}{2 - N}} d ζ \approx 0.1704829453 . \end{matrix}

Let

p_{1} = 6, p_{2} = 3

and

q = 2,

then

\frac{1}{p_{1}} + \frac{1}{p_{2}} + \frac{1}{q} = 1

and

\begin{matrix} β_{2} = \frac{r_{0}^{2}}{{(N - 2)}^{2}} ∥ \hat{Q} ∥_{q} \prod_{i = 1}^{κ} {∥ ϱ_{i} ∥}_{p_{i}} \approx 0.1255931381 . \end{matrix}

Let

\begin{matrix} F_{1} (z) = F_{2} (z) = \{\begin{matrix} 3.9, z \leq 1.8, \\ 3.9 {(z - 0.8)}^{2} + z - 1.8, z > 1.8 . \end{matrix} \end{matrix}

Choose

f = \frac{1}{3}, g = \frac{1}{2}

and

h = \frac{3}{5} .

Then,

\begin{matrix} F_{1} (z) = F_{2} (z) & \geq 3.519413622 = \frac{h}{β_{1}}, z \in [\frac{3}{5}, 3.461 \times \frac{3}{5}], \\ F_{1} (z) = F_{2} (z) & \leq 3.981109220 = \frac{g}{β_{2}}, z \in [0, 3.461 \times \frac{1}{2}], \\ F_{1} (z) = F_{2} (z) & \geq 1.955229790 = \frac{f}{β_{1}}, z \in [\frac{1}{3}, 3.461 \times \frac{1}{3}] . \end{matrix}

Hence, by an application of Theorem 4, the BVP (9) and (10) has coupled positive solutions

(^{β} z_{_{1}},^{β} z_{2}), β = 1, 2

, such that

\frac{1}{3} < max_{\hat{r} \in [0, 1]}^{β} z_{_{1}} (\hat{r}) with max_{\hat{r} \in [0, 1]}^{β} z_{_{1}} (\hat{r}) < \frac{1}{2}, for β = 1, 2,

\frac{1}{2} < max_{\hat{r} \in [0, 1]}^{β} z_{2} (\hat{r}) with min_{\hat{r} \in [0, 1]}^{β} z_{2} (\hat{r}) < \frac{3}{5}, for β = 1, 2 .

5. Uniqueness of Positive Radial Solution

We use two metrics, in accordance with Rus’ theorem [31,32], in this part, to test if there is a unique positive solution to the BVP (3). Consider the collection of continuous, real-valued functions defined on

[0, 1]

: this space is symbolised by the letter

X .

Take into account the below metrics on

X,

for functions

y, z \in X :

d (y, z) = max_{\hat{r} \in [0, 1]} | y (\hat{r}) - z (\hat{r}) |;

(11)

ρ (y, z) = {[\int_{0}^{1} {| y (\hat{r}) - z (\hat{r}) |}^{p} d \hat{r}]}^{\frac{1}{p}}, p > 1 .

(12)

The combination

(X, d)

creates a complete metric space for

d

in (11). Then,

(X, ρ)

constitutes a metric space for the value of

ρ

in (12). The equation expressing the connection between the two measures on

X

is

ρ (y, z) \leq d (y, z) for all y, z \in X .

(13)

Theorem 10 (Rus [32]).

Let

F : X \to X

be a continuous with respect to

d

on

X

and

d (F y, F z) \leq α_{1} ρ (y, z),

(14)

for some

α_{1} > 0

and for all

y, z \in X,

ρ (F y, F z) \leq α_{2} ρ (y, z),

(15)

for some

0 < α_{2} < 1

for all

y, z \in X,

then there is a unique

y^{*} \in X

such that

F y^{*} = y^{*} .

Denote

Υ (ζ) = Q (ζ, ζ) ζ^{\frac{2 (N - 1)}{2 - N}} \prod_{i = 1}^{κ} ϱ_{i} (ζ) .

Theorem 11.

Suppose that

(J_{1})

and

(J_{2})

and the following

$(J_{12})$: $| F_{β} (z) - F_{β} (y) | \leq K | z - y | for z, y \in X,$ for some $K > 0$

are satisfied. Furthermore, there are two real numbers

p > 1, q > 1

satisfying

\frac{1}{p} + \frac{1}{q} = 1

, and the following holds:

{[\frac{σ (ξ) K r_{0}^{2}}{{(N - 2)}^{2}}]}^{d + 1} {[\int_{0}^{1} | Υ (ζ) | d ζ]}^{d} {[\int_{0}^{1} {| Υ (ζ) |}^{q} d ζ]}^{\frac{1}{q}} < 1;

(16)

then the BVP (3) has a unique positive solution in

X .

Proof.

Let

z_{_{1}}, y_{1} \in X

and

ζ_{n - 1} \in [0, 1] .

The Hölder’s inequality gives

\begin{matrix} | \int_{0}^{1} & Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d} - \int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (y_{1} (ζ_{d})) d ζ_{d} | \\ \leq \int_{0}^{1} | Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) | | F_{d} (z_{_{1}} (ζ_{d})) - F_{d} (y_{1} (ζ_{d})) | d ζ_{d} \\ \leq \int_{0}^{1} | Q (ζ_{d}, ζ_{d}) ϱ (ζ_{d}) | K | z_{_{1}} (ζ_{d}) - y_{1} (ζ_{d}) | d ζ_{d} \leq \frac{K r_{0}^{2}}{{(d - 2)}^{2}} \int_{0}^{1} | Υ (ζ_{d}) | | z_{_{1}} (ζ_{d}) - y_{1} (ζ_{d}) | d ζ_{d} \\ \leq \frac{K r_{0}^{2}}{{(N - 2)}^{2}} {[\int_{0}^{1} {| Υ (ζ_{d}) |}^{q} d ζ_{d}]}^{\frac{1}{q}} {[\int_{0}^{1} {| z_{_{1}} (ζ_{d}) - y_{1} (ζ_{d}) |}^{p} d ζ_{d}]}^{\frac{1}{p}} \\ \leq \frac{K r_{0}^{2}}{{(N - 2)}^{2}} {[\int_{0}^{1} {| Υ (ζ_{d}) |}^{q} d ζ_{d}]}^{\frac{1}{q}} ρ (z_{_{1}}, y_{1}) \leq α_{1}^{★} ρ (z_{_{1}}, y_{1}), \end{matrix}

where

α_{1}^{★} = \frac{K r_{0}^{2}}{{(N - 2)}^{2}} {[\int_{0}^{1} {| Υ (ζ_{d}) |}^{q} d ζ]}^{\frac{1}{q}} .

Similarly, for

0 < ζ_{d - 2} < 1,

we obtain

\begin{matrix} | \int_{0}^{1} & Q (ζ_{d - 2}, ζ_{d - 1}) ϱ (ζ_{d - 1}) F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (z_{_{1}} (ζ_{d})) d ζ_{d}] d ζ_{d - 1} \\ - \int_{0}^{1} Q (ζ_{d - 2}, ζ_{d - 1}) ϱ (ζ_{d - 1}) F_{d - 1} [\int_{0}^{1} Q (ζ_{d - 1}, ζ_{d}) ϱ (ζ_{d}) F_{d} (y_{1} (ζ_{d})) d ζ_{d}] d ζ_{d - 1} | \\ \leq \frac{K r_{0}^{2}}{{(N - 2)}^{2}} \int_{0}^{1} | Υ (ζ_{d - 1}) | α_{1} ρ (z_{_{1}}, y_{1}) d ζ_{d - 1} \leq {\hat{α}}_{1} α_{1}^{★} ρ (z_{_{1}}, y_{1}), \end{matrix}

where

{\hat{α}}_{1} = \frac{K r_{0}^{2}}{{(N - 2)}^{2}} \int_{0}^{1} | Υ (ζ) | d ζ .

Thus, we have

|F z_{_{1}} (ζ) - F y_{1} (ζ)| \leq {\hat{α}}_{1}^{d} α_{1}^{★} ρ (z_{_{1}}, y_{1});

that is,

d (F z_{_{1}}, F y_{1}) \leq α_{1} ρ (z_{_{1}}, y_{1}),

(17)

for some

α_{1} = {\hat{α}}_{1}^{d} α_{1}^{★} > 0

for all

z_{_{1}}, y_{1} \in X,

this proves (14). Next, let

z_{_{1}}, y_{1} \in X,

and from (13) and (17), we obtain

d (F z_{_{1}}, F y_{1}) \leq α_{1} ρ (z_{_{1}}, y_{1}) \leq α_{1} d (z_{_{1}}, y_{1}) .

Thus, for

ε > 0,

select

η = ε / α_{1},

we obtain

d (F z_{_{1}}, F y_{1}) < ε,

whenever

d (z_{_{1}}, y_{1}) < η,

which shows that

F

is continuous on

X

with metric

d .

It remains to be shown that

F

is contractive on

X

with metric

ρ .

For each

z_{_{1}}, y_{1} \in X,

and from (17), we have

\begin{matrix} {[\int_{0}^{1} {| (F z_{_{1}}) (ζ) - (F y_{1}) (ζ) |}^{p} d ζ]}^{\frac{1}{p}} & \leq {[\int_{0}^{1} {|{\hat{α}}_{1}^{d} α_{1}^{★} ρ (z_{_{1}}, y_{1})|}^{p} d ζ]}^{\frac{1}{p}} \\ \leq {[\frac{K r_{0}^{2}}{{(N - 2)}^{2}}]}^{d + 1} {[\int_{0}^{1} | Υ (ζ) | d ζ]}^{d} {[\int_{0}^{1} {| Υ (ζ) |}^{q} d ζ]}^{\frac{1}{q}} ρ (z_{_{1}}, y_{1}); \end{matrix}

that is

\begin{matrix} ρ (F z_{_{1}}, F y_{1}) \leq {[\frac{K r_{0}^{2}}{{(N - 2)}^{2}}]}^{d + 1} {[\int_{0}^{1} | Υ (ζ) | d ζ]}^{d} {[\int_{0}^{1} {| Υ (ζ) |}^{q} d ζ]}^{\frac{1}{q}} ρ (z_{_{1}}, y_{1}) . \end{matrix}

From assumption (16), we have

ρ (F z_{_{1}}, F y_{1}) \leq α_{2} ρ (z_{_{1}}, y_{1})

for some

α_{2} < 1

and all

z_{_{1}}, y_{1} \in X .

It follows from Theorem 10 that

F

has a unique fixed point in

X .

Moreover, from Lemma 3,

F

is positive. Hence, the BVP (1) has a unique positive solution. □

Example 3.

Consider the problem,

▵ z_{_{β}} - \frac{{(N - 2)}^{2} r_{0}^{2 N - 2}}{{| ν |}^{2 N - 2}} z_{_{β}} + ϱ (| ν |) F_{β} (z_{_{β + 1}}) = 0, 1 < | ν | < 2,

(18)

z_{_{β}} (0) = z_{_{β}} (1) = 0,

(19)

where

r_{0} = 1,

N = 3,

β \in {1, 2}, z_{3} = z_{_{1}},

ϱ (\hat{r}) = \frac{1}{{\hat{r}}^{4}} \prod_{i = 1}^{2} ϱ_{i} (\hat{r}),

ϱ_{i} (\hat{r}) = ϱ_{i} (\frac{1}{\hat{r}}),

in which

ϱ_{1} (\hat{r}) = ϱ_{2} (\hat{r}) = \frac{{\hat{r}}^{3}}{\sqrt{\hat{r} + 1}}

. Let

F_{1} (z) = \frac{3}{2} sin (z)

and

F_{2} (z) = \frac{3}{2 (z + 1)};

then,

| F_{1} (z) - F_{1} (y) | = \frac{| sin (z) - sin (y) |}{10^{3}} \leq \frac{3}{2} | z - y |

and

| F_{2} (z) - F_{2} (y) | = \frac{3}{2} |\frac{1}{z + 1} - \frac{1}{y + 1}| \leq \frac{3}{2} | z - y | .

Thus,

K = \frac{3}{2} .

Let

d = 2

and

p = q = 2;

then,

{[\frac{K r_{0}^{2}}{{(N - 2)}^{2}}]}^{d + 1} {[\int_{0}^{1} | Υ (ζ) | d ζ]}^{d} {[\int_{0}^{1} {| Υ (ζ) |}^{q} d ζ]}^{\frac{1}{q}} \approx 0.1508078067 < 1 .

Hence, as an application of Theorem 11, the BVP (18) and (19) has a unique positive radial solution.

6. Conclusions

In this paper, we developed a theory to study the existence of single and coupled positive radial solutions for a certain type of iterative system of nonlinear elliptic equations, by applying Krasnoselskii’s and Avery–Henderson’s fixed-point theorems in a Banach space. In the future, we will study the existence of positive radial solutions for an iterative system of elliptic equations with a logarithmic nonlinear term. In addition, we will study global existence and ground-state solutions to the addressed problem.

Author Contributions

Conceptualization, X.W. and J.A.; methodology, M.K.; software, validation, M.F.; writing—original draft preparation, M.K.; writing—review and editing, J.A. and M.K. All authors have read and agreed to the published version of the manuscript.

Funding

This research is supported by the National Natural Science Foundation of China (Grant No. 11861053).

Institutional Review Board Statement

This article does not contain any studies, performed by any of the authors, involving human participants or animals.

Data Availability Statement

Data sharing not applicable to this paper, as no data sets were generated or analyzed during the current study.

Acknowledgments

The authors would like to thank the referees for their valuable suggestions and comments for the improvement of the paper. Xiaoming Wang is thankful to the National Natural Science Foundation of China (Grant No. 11861053). J. Alzabut is thankful to Prince Sultan University and OSTİM Technical University, and Mahammad Khuddush is thankful to Lankapalli Bullayya College of Engineering for their tireless support during work on this paper. M. Fečkan is thankful to the Slovak Research and Development Agency, under contract No. APVV-18-0308, and to the Slovak Grant Agency VEGA No. 1/0084/23 and No. 2/0127/20.

Conflicts of Interest

The authors declare no conflict of interest.

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Wang, X.; Alzabut, J.; Khuddush, M.; Fečkan, M. Solvability of Iterative Classes of Nonlinear Elliptic Equations on an Exterior Domain. Axioms 2023, 12, 474. https://doi.org/10.3390/axioms12050474

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Wang X, Alzabut J, Khuddush M, Fečkan M. Solvability of Iterative Classes of Nonlinear Elliptic Equations on an Exterior Domain. Axioms. 2023; 12(5):474. https://doi.org/10.3390/axioms12050474

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Wang, Xiaoming, Jehad Alzabut, Mahammad Khuddush, and Michal Fečkan. 2023. "Solvability of Iterative Classes of Nonlinear Elliptic Equations on an Exterior Domain" Axioms 12, no. 5: 474. https://doi.org/10.3390/axioms12050474

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Solvability of Iterative Classes of Nonlinear Elliptic Equations on an Exterior Domain

Abstract

1. Introduction

2. Preliminaries

3. Single Positive Radial Solution

4. Existence of Coupled Positive Radial Solutions

5. Uniqueness of Positive Radial Solution

6. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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