Growth estimates for modified Neumann integrals in a half-space

Our aim in this paper is to deal with the growth properties for modified Neumann integrals in a half-space of ${\mathbf{R}}^n$. As an application, the solutions of Neumann problems in it for a slowly growing continuous function are also given.

Let R and ${\mathbf{R}}_{+}$ be the sets of all real numbers and of all positive real numbers, respectively. Let ${\mathbf{R}}^n$ ($n\ge 3$) denote the n-dimensional Euclidean space with points $x=(x^{\prime },x_n)$, where $x^{\prime }=(x_1,x_2,\dots ,x_{n-1})\in {\mathbf{R}}^{n-1}$ and $x_n\in \mathbf{R}$. The boundary and closure of an open set Ω of ${\mathbf{R}}^n$ are denoted by ∂ Ω and $\overline{\mathrm{\Omega }}$, respectively. For $x\in {\mathbf{R}}^n$ and $r>0$, let $B_n(x,r)$ denote the open ball with center at x and radius r in ${\mathbf{R}}^n$.

The upper half-space is the set $H=\{(x^{\prime },x_n)\in {\mathbf{R}}^n:x_n>0\}$, whose boundary is ∂H. For a set F, $F\subset {\mathbf{R}}_{+}\cup \{0\}$, we denote $\{x\in H;|x|\in F\}$ and $\{x\in \partial H;|x|\in F\}$ by HF and $\partial HF$, respectively. We identify ${\mathbf{R}}^n$ with ${\mathbf{R}}^{n-1}\times \mathbf{R}$ and ${\mathbf{R}}^{n-1}$ with ${\mathbf{R}}^{n-1}\times \{0\}$, writing typical points $x,y\in {\mathbf{R}}^n$ as $x=(x^{\prime },x_n)$, $y=(y^{\prime },y_n)$, where $y^{\prime }=(y_1,y_2,\dots ,y_{n-1})\in {\mathbf{R}}^{n-1}$. Let θ be the angle between x and ${\hat{e}}_n$, i.e., $x_n=|x|cos\theta$ and $0\le \theta <\pi /2$, where ${\hat{e}}_n$ is the i th unit coordinate vector and ${\hat{e}}_n$ is normal to ∂H.

We shall say that a set $E\subset H$ has a covering $\{r_j,R_j\}$ if there exists a sequence of balls $\{B_j\}$ with centers in H such that $E\subset {\bigcup }_{j=0}^{\mathrm{\infty }}{B}_j$, where $r_j$ is the radius of $B_j$ and $R_j$ is the distance between the origin and the center of $B_j$.

For positive functions $g_1$ and $g_2$, we say that $g_1\lesssim g_2$ if $g_1\le M{g}_2$ for some positive constant M. Throughout this paper, let M denote various constants independent of the variables in question. Further, we use the standard notations, $[d]$ is the integer part of d and $d=[d]+\{d\}$, where d is a positive real number.

Given a continuous function f in ∂H, we say that h is a solution of the Neumann problem in H with f, if h is a harmonic function in H and

for every point $y^{\prime }\in \partial H$.

For $x\in {\mathbf{R}}^n$ and $y^{\prime }\in {\mathbf{R}}^{n-1}$, consider the kernel function

where ${\beta }_n=2/(n-2){\sigma }_n$ and ${\sigma }_n$ is the surface area of the n-dimensional unit sphere. It has the expression

where $C_k^{\frac{n}{2}}(t)$ is the ultraspherical (Gegenbauer) polynomials [1]. The series converges for $|y^{\prime }|>|x|$, and each term in it is a harmonic function of x.

The Neumann integral is defined by

where f is a continuous function on ∂H, ${\alpha }_n=2/n{\sigma }_n$ and ${\sigma }_n={\pi }^{\frac{n}{2}}/\mathrm{\Gamma }(1+\frac{n}{2})$ is the volume of the unit n-ball.

The Neumann integral $N[f](x)$ is a solution of the Neumann problem on H with f if (see [[2], Theorem 1 and Remarks])

In this paper, we consider functions f satisfying

for $1\le p<\mathrm{\infty }$ and $\alpha \in \mathbf{R}$.

For this p and α, we define the positive measure μ on ${\mathbf{R}}^n$ by

If f is a measurable function on ∂H satisfying (1.1), we remark that the total mass of μ is finite.

Let $ϵ>0$ and $\delta \ge 0$. For each $x\in {\mathbf{R}}^n$, the maximal function $M(x;\mu ,\delta )$ is defined by

The set $\{x\in {\mathbf{R}}^n;M(x;\mu ,\delta )>ϵ\}$ is denoted by $E(ϵ;\mu ,\delta )$.

To obtain the Neumann solution for the boundary data f, as in [3–6], we use the following modified kernel function defined by

for a non-negative integer m.

For $x\in {\mathbf{R}}^n$ and $y^{\prime }\in {\mathbf{R}}^{n-1}$, the generalized Neumann kernel is defined by

Since $|x{|}^k{C}_k^{\frac{n-2}{2}}(\frac{x\cdot y^{\prime }}{|x||y^{\prime }|})$ ($k\ge 0$) is harmonic in H (see [4]), $K_{n,m}(\cdot ,y^{\prime })$ is also harmonic in H for any fixed $y^{\prime }\in \partial H$. Also, $K_{n,m}(x,y^{\prime })$ will be of order $|y^{\prime }{|}^{-(n+m-2)}$ as $y^{\prime }\to \mathrm{\infty }$ (see [[7], Theorem D]).

Put

where f is a continuous function on ∂H. Here, note that $N_0[f](x)$ is nothing but the Neumann integral $N[f](x)$.

The following result is due to Siegel and Talvila (see [[5], Corollary 2.1]). For similar results with respect to the Schrödinger operator in a half-space, we refer readers to papers by Su (see [8]).

Theorem A If f is a continuous function on ∂H satisfying (1.1) with $p=1$ and $\alpha =m$, then

The next result deals with a type of uniqueness of solutions for the Neumann problem on H (see [[9], Theorem 3]).

Theorem B Let l be a positive integer and m be a non-negative integer. If f is a continuous function on ∂H satisfying

and h is a solution of the Neumann problem on H with f such that

then

for any $x=(x^{\prime },x_n)\in H$, where $h^{+}(x)$ is the positive part of h,

and $\mathrm{\Pi }(x^{\prime })$ is a polynomial of $x^{\prime }\in {\mathbf{R}}^{n-1}$ of degree less than $l+m$.

Our first aim is to be concerned with the growth property of $N_m[f]$ at infinity and establish the following theorem.

Theorem 1 Let $1\le p<\mathrm{\infty }$, $0\le \beta \le (n-2)p$, $n+\alpha -2>-(n-1)(p-1)$ and

If f is a measurable function on ∂ satisfying (1.1), then there exists a covering $\{r_j,R_j\}$ of $E(ϵ;\mu ,(n-2)p-\beta )$ (⊂H) satisfying

such that

Corollary 1 Let $1<p<\mathrm{\infty }$, $n+\alpha -2>-(n-1)(p-1)$ and

If f is a measurable function on ∂H satisfying (1.1), then

As an application of Theorem 1, we now show the solution of the Neumann problem with continuous data on H.

Theorem 2 Let p, β, α and m be defined as in Theorem  1. If f is a continuous function on ∂H satisfying (1.1), then the function $N_m[f]$ is a solution of the Neumann problem on H with f and (1.4) holds, where the exceptional set $E(ϵ;\mu ,(n-2)p-\beta )$ (⊂H) has a covering $\{r_j,R_j\}$ satisfying (1.3).

Remark In the case $p=1$, $\alpha =m$ and $\beta =n-2$, then (1.3) is a finite sum and the set $E(ϵ;\mu ,0)$ is a bounded set. So (1.4) holds in H. That is to say, (1.2) holds. This is just the result of Theorem A.

Corollary 2 Let $1\le p<\mathrm{\infty }$, $n+\alpha -2>-(n-1)(p-1)$ and

If f is a continuous function on ∂H satisfying (1.1), then the function $N_m[f]$ is a solution of the Neumann problem on H with f and (1.5) holds.

The following result extends Theorem B, which is our result in the case $p=1$ and $\alpha =m$.

Theorem 3 Let $1\le p<\mathrm{\infty }$, $\alpha >1-p$, l be a positive integer and

If f is a continuous function on ∂H satisfying (1.1) and h is a solution of the Neumann problem on H with f such that

then

for any $x=(x^{\prime },x_n)\in H$ and $\mathrm{\Pi }(x^{\prime })$ is a polynomial of $x^{\prime }\in {\mathbf{R}}^{n-1}$ of degree less than $l+[1+\frac{\alpha -1}{p}]$.

In our discussions, the following estimates for the kernel function $K_{n,m}(x,y^{\prime })$ are fundamental (see [[10], Lemma 4.2] and [[4], Lemmas 2.1 and 2.4]).

Lemma 1

1. (1)

   If $1\le |y^{\prime }|\le \frac{|x|}{2}$, then $|K_{n,m}(x,y^{\prime })|\lesssim |x{|}^{m-1}|y^{\prime }{|}^{-n-m+3}$.

2. (2)

   If $\frac{|x|}{2}<|y^{\prime }|\le \frac{3}{2}|x|$, then $|K_{n,m}(x,y^{\prime })|\lesssim |x-y^{\prime }{|}^{2-n}$.

3. (3)

   If $\frac{3}{2}|x|<|y^{\prime }|\le 2|x|$, then $|K_{n,m}(x,y^{\prime })|\lesssim x_n^{2-n}$.

4. (4)

   If $|y^{\prime }|\ge 2|x|$ and $|y^{\prime }|\ge 1$, then $|K_{n,m}(x,y^{\prime })|\lesssim |x{|}^m|y^{\prime }{|}^{2-n-m}$.

The following lemma is due to Qiao (see [4]).

Lemma 2 If $ϵ>0$, $\eta \ge 0$ and λ is a positive measure in ${\mathbf{R}}^n$ satisfying $\lambda ({\mathbf{R}}^n)<\mathrm{\infty }$, then $E(ϵ;\lambda ,\eta )$ has a covering $\{r_j,R_j\}$ ($j=1,2,\dots$) such that

Lemma 3 ([[9], Lemma 4])

Let p, β, α and m be defined as in Theorem  1. If f is a locally integral and upper semi-continuous function on ∂H satisfying (1.1), then

for any fixed $y^{\prime }\in \partial H$.

Lemma 4 ([[2], Lemma 1])

If $h(x)$ is a harmonic polynomial of $x=(x^{\prime },x_n)\in H$ of degree m and $\partial h/\partial x_n$ vanishes on ∂H, then there exists a polynomial $\mathrm{\Pi }(x^{\prime })$ of degree m such that

For any $ϵ>0$, there exists $R_{ϵ}>1$ such that

Take any point $x\in H(R_{ϵ},\mathrm{\infty })-E(ϵ;\mu ,(n-2)p-\beta )$ such that $|x|>2R_{ϵ}$, and write

where

First note that

so that

If $m<2-\frac{1-\alpha }{p}$ and $\frac{1}{p}+\frac{1}{q}=1$, then $(3-n-m+\frac{n+\alpha -2}{p})q+n-1>0$. By Lemma 1(1), (3.1) and the Hölder inequality, we have

Put

where

If $|x|\ge 2R_{ϵ}$, then

Moreover, by (3.1) and (3.3), we get

That is,

By Lemma 1(3), (3.1) and the Hölder inequality, we have

If $m>1-\frac{1-\alpha }{p}$, then $(2-n-m+\frac{n+\alpha -2}{p})q+n-1<0$. We obtain, by Lemma 1(4), (3.1) and the Hölder inequality,

Finally, we shall estimate $U_3(x)$. Take a sufficiently small positive number b such that $\partial H[\frac{|x|}{2},\frac{3}{2}|x|]\subset B(x,\frac{|x|}{2})$ for any $x\in \mathrm{\Pi }(b)$, where

and divide H into two sets $\mathrm{\Pi }(b)$ and $H-\mathrm{\Pi }(b)$.

If $x\in H-\mathrm{\Pi }(b)$, then there exists a positive number $b^{\prime }$ such that $|x-y^{\prime }|\ge b^{\prime }|x|$ for any $y^{\prime }\in \partial H$, and hence

which is similar to the estimate of $U_5(x)$.

We shall consider the case $x\in \mathrm{\Pi }(b)$. Now put

where $\delta (x)={inf}_{y^{\prime }\in H}|x-y^{\prime }|$.

Since $\partial H\cap \{y^{\prime }\in {\mathbf{R}}^{n-1}:|x-y^{\prime }|<\delta (x)\}=\mathrm{\varnothing }$, we have

where $i(x)$ is a positive integer satisfying $2^{i(x)-1}\delta (x)\le \frac{|x|}{2}<2^{i(x)}\delta (x)$.

Similar to the estimate of $U_5(x)$, we obtain

for $i=0,1,2,\dots ,i(x)$.

Since $x\notin E(ϵ;\mu ,(n-2)p-\beta )$, we have

for $i=0,1,2,\dots ,i(x)-1$ and

So

Combining (3.2), (3.4)-(3.7), we obtain that if $R_{ϵ}$ is sufficiently large and ϵ is a sufficiently small number, then $N_m[f](x)=o(|x{|}^{1+\frac{\alpha -1}{p}}{sec}^{\frac{\beta }{p}}\theta )$ as $|x|\to \mathrm{\infty }$, where $x\in H(R_{ϵ},+\mathrm{\infty })-E(ϵ;\mu ,(n-2)p-\beta )$. Finally, there exists an additional finite ball $B_0$ covering $H(0,R_{ϵ}]$, which together with Lemma 2, gives the conclusion of Theorem 1.

For any fixed $x\in H$, take a number R satisfying $R>max\{1,2|x|\}$. If $m>\frac{1-\alpha }{p}$, then $(2-n-m+\frac{n+\alpha -2}{p})q+n-1<0$. By (1.1), Lemma 1(4) and the Hölder inequality, we have

Hence $N_m[f](x)$ is absolutely convergent and finite for any $x\in H$. Thus $N_m[f](x)$ is harmonic on H.

To prove

for any point $y^{\prime }\in \partial H$, we only need to apply Lemma 3 to $f(y)$ and $-f(y)$.

We complete the proof of Theorem 2.

Consider the function $h^{\prime }(x)=h(x)-N_m[f](x)$. Then it follows from Theorems 2 and 3 that $h^{\prime }(x)$ is a solution of the Neumann problem on H with f and it is an even function of $x_n$ (see [[2], p.92]).

Since

for any $x\in H$, and

from Theorem 2.

Moreover, (1.6) gives that

This implies that $h^{\prime }(x)$ is a polynomial of degree less than $l+[1+\frac{\alpha -1}{p}]$ (see [[11], Appendix]), which gives the conclusion of Theorem 3 from Lemma 4.

The authors are thankful to the referees for their helpful suggestions and necessary corrections in the completion of this paper.

Authors and Affiliations

1. Department of Mathematics and Information Science, Henan University of Economics and Law, Zhengzhou, 450002, P.R. China

   Yudong Ren

2. College of Applied Mathematics, Chengdu University of Information Technology, Chengdu, 610225, P.R. China

   Pai Yang

Corresponding author

Correspondence to Yudong Ren.

Competing interests

The authors declare that there is no conflict of interests regarding the publication of this article.

Authors’ contributions

All authors contributed equally to the manuscript and read and approved the final manuscript.

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