Boundedness of rough fractional multilinear integral operators on generalized Morrey spaces

We consider the boundedness of fractional multilinear integral operators with rough kernels \(T_{\Omega,\alpha}^{A,m}\) on the generalized Morrey spaces \(M_{p,\varphi}\). We find the sufficient conditions on the pair \((\varphi_{1},\varphi _{2})\), which ensures the boundedness of the operators \(T_{\Omega,\alpha}^{A,m}\) from \(M_{p,\varphi_{1}}\) to \(M_{p,\varphi_{2}}\) for \(1< p<\infty\). In all cases the conditions for the boundedness of the operator \(T_{\Omega,\alpha}^{A,m}\) is given in terms of Zygmund-type integral inequalities on \((\varphi_{1},\varphi_{2})\), which do not make any assumption on the monotonicity of \(\varphi_{1}(x,r)\), \(\varphi_{2}(x,r)\) in r.

The classical Morrey spaces were originally introduced by Morrey in [1] to study the local behavior of solutions to second order elliptic partial differential equations. For the properties and applications of classical Morrey spaces, we refer the readers to [1–9]. Mizuhara [10] introduced generalized Morrey spaces. Later, Guliyev [5] defined the generalized Morrey spaces \(M_{p,\varphi}\) with normalized norm.

Suppose that \(\Omega\in L_{s}({\mathbb{S}}^{n-1})\) (\(s>1\)) is homogeneous of degree zero on \({\mathbb{R}^{n}}\) with zero means value on \({\mathbb{S}}^{n-1}\), A is a function defined on \({\mathbb {R}^{n}}\). Following [11], the rough fractional multilinear integral operator \(T_{\Omega,\alpha}^{A,m}\) is defined by

where \(0<\alpha<n\), and \(R_{m}(A;x,y)\) is the mth remainder of Taylor series of A at x about y. More precisely,

When \(m=1\), then \(T_{\Omega,\alpha}^{A} \equiv T_{\Omega,\alpha }^{A,1}\) is just the commutator of the fractional integral \(T_{\Omega ,\alpha}f(x)\) with function A,

The weighted \((L_{p},L_{q})\)-boundedness of such a commutator is given by Ding and Lu in [12]. When \(m\ge2\), \(T_{\Omega,\alpha}^{A}\) is a non-trivial generalization of the above commutator. In [13], Wu and Yang proved the following result.

Theorem A

Suppose that \(\Omega\in L_{s}({\mathbb{S}}^{n-1})\) and assume that A has derivatives of order \(m-1\) in \(\mathit{BMO}({\mathbb{R}^{n}})\). Let \(m \ge2\), \(0<\alpha <n\), \(1\le s'< p< n/\alpha\), and \(1/q=1/p-\alpha/n\). Then there exists a constant C, independent of A and f, such that

Here and in the sequel, we always denote by \(p'\) the conjugate index of any \(p>1\), that is, \(1/p+1/p'=1\), and by C a constant which is independent of the main parameters and may vary from line to line.

The commutators are useful in many nondivergence elliptic equations with discontinuous coefficients [3, 14–16]. In the recent development of commutators, Pérez and Trujillo-González [17] generalized these multilinear commutators and proved the weighted Lebesgue estimates.

In [18], Guliyev proved the following result.

Theorem B

Let \(0 < \alpha< n\), \(1 < p < n/\alpha\), and \(1/q=1/p-\alpha /n\), \(\Omega\in L_{s}({\mathbb{S}}^{n-1})\), \(1< s \le\infty \), \(A \in \mathit{BMO}\), and \((\varphi_{1},\varphi_{2})\) satisfies the condition

where C does not depend on x and r. Then the operator \(T_{\Omega ,\alpha}^{A}\) is bounded from \(M_{p,\varphi_{1}}\) to \(M_{q,\varphi_{2}}\).

It has been proved by many authors that most of the operators which are bounded on a Lebesgue space are also bounded in an appropriate Morrey space; see [19]. As far as we know, there is no research regarding the boundedness of the fractional multilinear integral operator on Morrey space.

In this paper, we are going to prove that these results are valid for the rough fractional multilinear integral operator \(T_{\Omega,\alpha }^{A,m}\) on generalized Morrey spaces. Our main results can be formulated as follows.

Theorem 1.1

Let \(0 < \alpha< n\), \(1\le s' < p < n/\alpha\), and \(1/q=1/p-\alpha/n\). Suppose that \(\Omega\in L_{s}({\mathbb{S}}^{n-1})\) and \((\varphi _{1},\varphi_{2})\) satisfy the condition

where \(C_{0}\) does not depend on x and r. If A has derivatives of order \(m-1\) in \(\mathit{BMO}({\mathbb{R}^{n}})\), then the operator \(T_{\Omega,\alpha}^{A,m}\) is bounded from \(M_{p,\varphi_{1}}({\mathbb{R}^{n}})\) to \(M_{q,\varphi_{2}}({\mathbb {R}^{n}})\). Moreover, then there is a constant \(C>0\) independent of f such that

Remark 1.1

Note that in the case \(m=1\) from Theorem 1.1 we get Theorem B.

The classical Morrey spaces \(M_{p,\lambda}\) were originally introduced by Morrey in [1] to study the local behavior of solutions to second order elliptic partial differential equations. For the properties and applications of classical Morrey spaces, we refer the readers to [20, 21].

We denote by \(M_{p,\lambda} \equiv M_{p,\lambda}({\mathbb{R}^{n}})\) the Morrey space, the space of all functions \(f\in L_{p}^{\mathrm{loc}}({\mathbb{R}^{n}})\) with finite quasinorm,

where \(1\le p < \infty\) and \(0 \le\lambda\le n\).

Note that \(M_{p,0}=L_{p}({\mathbb{R}^{n}})\) and \(M_{p,n}=L_{\infty }({\mathbb{R}^{n}})\). If \(\lambda<0\) or \(\lambda>n\), then \(M_{p,\lambda}={\Theta}\), where Θ is the set of all functions equivalent to 0 on \({\mathbb{R}^{n}}\).

In [10], Mizuhara introduced the generalized Morrey spaces \(\mathcal{M}_{p,\varphi}({\mathbb{R}^{n}})\) in the following form and discussed the boundedness of the Calderón-Zygmund singular integral operators.

Definition 2.1

Let \(\varphi(x,r)\) be a positive measurable function on \({\mathbb {R}^{n}}\times (0,\infty)\) and \(1 \le p < \infty\). We denote by \(\mathcal{M}_{p,\varphi} \equiv\mathcal{M}_{p,\varphi }({\mathbb{R}^{n}})\) the generalized Morrey space, the space of all functions \(f\in L_{p}^{\mathrm{loc}}({\mathbb{R}^{n}})\) with finite quasinorm

Note that the generalized Morrey spaces \(M_{p,\varphi} \equiv M_{p,\varphi}({\mathbb{R}^{n}})\) with normalized norm,

were first defined by Guliyev in [5].

Also, in [5], by \(\mathit{WM}_{p,\varphi} \equiv \mathit{WM}_{p,\varphi }({\mathbb{R}^{n}} )\) we denote the weak generalized Morrey space of all functions \(f\in WL_{p}^{\mathrm{loc}}({\mathbb{R}^{n}})\) for which

By the definition, we recover the Morrey space \(M_{p,\lambda}\) and weak Morrey space \(\mathit{WM}_{p,\lambda}\) under the choice \(\varphi(x,r)=r^{\frac{\lambda-n}{p}}\):

There are many papers discussing the conditions on \(\varphi(x,r)\) to obtain the boundedness of operators on the generalized Morrey spaces. For example, in [10], the function φ is supposed to be a positive growth function and satisfy the double condition: for all \(r>0\), \(\varphi(2r) \le D \varphi(r)\), where \(D \ge1\) is a constant independent of r. This type of conditions on φ is studied by many authors; see, for example, [22, 23]. In [24], the following statement was proved by Nakai for the Riesz potential \(I_{\alpha }\):

Theorem C

Let \(1\le p<\infty \), \(0 < \alpha < \frac {n}{p}\), \(\frac {1}{q}=\frac{1}{p}-\frac{\alpha }{n}\), and let \(\varphi(x,r)\) satisfy the conditions

whenever \(r \le t \le2r\), where c (\(c \ge1\)) does not depend on t, r, x, and

where C does not depend on x and r. Then the operator \(I_{\alpha }\) is bounded from \(M_{p,\varphi}\) to \(M_{q,\varphi}\) for \(p > 1\) and from \(M_{1,\varphi}\) to \(\mathit{WM}_{1,\varphi}\) for \(p=1\).

The following statements, containing the Mizuhara and Nakai results obtained in [10, 24], were proved by Guliyev in [5, 25] (see also [26]).

Theorem D

Let \(1\le p<\infty \), \(0 < \alpha < \frac {n}{p}\), \(\frac {1}{q}=\frac{1}{p}-\frac{\alpha }{n}\), and \((\varphi_{1},\varphi_{2})\) satisfy the condition

where C does not depend on x and r. Then the operator \(I_{\alpha }\) is bounded from \(M_{p,\varphi_{1}}\) to \(M_{q,\varphi_{2}}\) for \(p > 1\) and from \(M_{1,\varphi_{1}}\) to \(\mathit{WM}_{q,\varphi_{2}}\) for \(p=1\).

Recently, in [27] and [28], Guliyev et al. introduced a weaker condition for the boundedness of Riesz potential from \(M_{p,\varphi_{1}}\) to \(M_{q,\varphi_{2}}\).

Theorem E

Let \(1 \le p < \infty\), \(0<\alpha <\frac{n}{p}\), \(\frac{1}{q}=\frac{1}{p}-\frac{\alpha }{n}\), and \((\varphi_{1},\varphi_{2})\) satisfy the condition

where C does not depend on x and t. Then the operator \(I_{\alpha }\) is bounded from \(M_{p,\varphi_{1}}\) to \(M_{q,\varphi_{2}}\) for \(1< p< q<\infty \) and from \(M_{1,\varphi_{1}}\) to \(\mathit{WM}_{q,\varphi_{2}}\) for \(1< q<\infty \).

By an easy computation, we can check that if the pair \((\varphi _{1},\varphi_{2})\) satisfies the double condition, then it will satisfy condition (2.3). Moreover, if \((\varphi _{1},\varphi_{2})\) satisfies condition (2.3), it will also satisfy condition (2.4). But the opposite is not true. We refer to [24] and Remark 4.7 in [28] for details.

Let \(B=B(x_{0},r_{B})\) denote the ball with the center \(x_{0}\) and radius \(r_{B}\). For a given weight function ω and a measurable set E, we also denote the Lebesgue measure of E by \(|E|\). For any given \(\Omega\subseteq{\mathbb{R}^{n}}\) and \(0 < p < \infty\), denote by \(L_{p}(\Omega)\) the space of all function f satisfying

First we recall the definition of the space \(\mathit{BMO}({\mathbb{R}^{n}})\).

Definition 3.1

Suppose that \(f\in L_{1}^{\mathrm{loc}}({\mathbb{R}^{n}})\), let

where

Define

If one regards two functions whose difference is a constant as one, then space \(\mathit{BMO}({\mathbb{R}^{n}})\) is a Banach space with respect to norm \(\| \cdot \|_{\ast}\).

Remark 3.1

[29]

1. (1)

   The John-Nirenberg inequality: there are constants \(C_{1}, C_{2}>0\), such that, for all \(f \in \mathit{BMO}({\mathbb{R}^{n}})\) and \(\beta>0\),

   $$\bigl\vert \bigl\{ x \in B : \bigl\vert f(x)-f_{B}\bigr\vert > \beta \bigr\} \bigr\vert \le C_{1} |B| e^{-C_{2} \beta/\| f \|_{\ast}}, \quad \forall B \subset {\mathbb{R}^{n}}. $$
2. (2)

   The John-Nirenberg inequality implies that

   $$ \|f\|_{\ast}\approx\sup_{x\in{\mathbb{R}^{n}}, r>0} \biggl(\frac {1}{|B(x,r)|} \int_{B(x,r)}\bigl\vert f(y)-f_{B(x,r)}\bigr\vert ^{p} \,dy \biggr)^{\frac{1}{p}} $$

   (3.1)

   for \(1< p<\infty \).

3. (3)

   Let \(f\in \mathit{BMO}({\mathbb{R}^{n}})\). Then there is a constant \(C>0\) such that

   $$ \vert f_{B(x,r)}-f_{B(x,t)}\vert \le C \|f \|_{\ast}\ln\frac{t}{r} \quad \mbox{for } 0< 2r< t, $$

   (3.2)

   where C is independent of f, x, r, and t.

Lemma 3.1

[30]

Let b be a function in \(\mathit{BMO}({\mathbb{R}^{n}})\), \(1 \le p < \infty\), and \(r_{1}, r_{2} > 0\). Then

where \(C>0\) is independent of b, x, \(r_{1}\), and \(r_{2}\).

Below we present some conclusions as regards \(R_{m}(A;x,y)\).

Lemma 3.2

[21]

Suppose b be a function on \({\mathbb{R}^{n}}\) with the mth derivatives in \(L_{q}({\mathbb{R}^{n}})\), \(q > n\). Then

Lemma 3.3

Let \(x\in B(x_{0},r)\), \(y\in B(x_{0},2^{j+1}r)\setminus B(x_{0},2^{j}r)\). Then

Proof

For fixed \(x\in{\mathbb{R}}^{n}\), let

So

By Lemma 3.2, we get

Since \(x\in B(x_{0},r)\), \(y\in B(x_{0},2^{j+1}r)\setminus B(x_{0},2^{j}r)\), it is easy to see that \(2^{j-1}r \le|x-y| \le2^{j+2}r\). In this way, we have

Then

Therefore

Note that

Then

Thus

Combining with (3.4), (3.5), and (3.6), then (3.3) is proved. □

Finally, we present a relationship between essential supremum and essential infimum.

Lemma 3.4

[31]

Let f be a real-valued nonnegative function and measurable on E. Then

In the following theorem we get Guliyev-type local estimate (see, for example, [5, 25]) for the operator \(T_{\Omega,\alpha}^{A,m}\).

Theorem 4.1

Let \(\Omega\in L_{s}({\mathbb{S}}^{n-1})\), \(1\le s' < p < n/\alpha\), and let \(1/q = 1/p - \alpha/n\). Let A be a function defined on \({\mathbb{R}^{n}}\). Suppose that it has derivatives of order \(m-1\) in \(\mathit{BMO}({\mathbb{R}^{n}})\), then the inequality

holds for any ball \(B(x_{0},r)\), and for all \(f\in L_{p}^{\mathrm {loc}}({\mathbb{R}^{n}})\), where the constant C is independent of f, r, and \(x_{0}\).

Proof

We write f as \(f=f_{1}+f_{2}\), where \(f_{1}(y)=f(y)_{\chi _{B(x_{0},2r)}(y)}\), \(\chi_{B(x_{0},2r)}\) denotes the characteristic function of \(B(x_{0},2r)\). Then

Since \(f_{1}\in L_{p}({\mathbb{R}^{n}})\), by the boundedness of \(T^{A}_{\Omega ,\alpha}\) from \(L_{p}({\mathbb{R}^{n}})\) to \(L_{q}({\mathbb{R}^{n}})\) (Theorem A) we get

Moreover,

Thus

Let \(\triangle_{i}=(B(x_{0},2^{j+1}r))\setminus(B(x_{0},2^{j}r))\), and let \(x\in B(x_{0},r)\). By Lemma 3.3 we get

By Hölder’s inequality we have

When \(x \in B(x_{0},s)\) and \(y\in\triangle_{i}\), then by a direct calculation, we can see that \(2^{j-1}r\le|y-x|<2^{j+1}r\). Hence

We also note that if \(x\in B(x_{0},r)\), \(y\in B(x_{0},2r)^{c}\), then \(\frac {1}{2} |x_{0}-y| \le|x-y| \le\frac{3}{2} |x_{0}-y|\). Consequently

Then

Since \(s' < p\), it follows from Hölder’s inequality that

Then

Then

On the other hand, by Hölder’s inequality and (4.4), (4.5), we have

Applying Hölder’s inequality we get

Consequently,

Then it follows from Lemma 3.1 that

Then

Combining the estimates of \(I_{1}\) and \(I_{2}\), we have

Then we get

This completes the proof of Theorem 4.1. □

Since \(f\in M_{p,\varphi_{1}}({\mathbb{R}^{n}})\), by Lemma 3.4 and the non-decreasing, with respect to t, of the norm \(\|f\| _{L_{p}(B(x_{0},t))}\), we get

Since \((\varphi_{1},\varphi_{2})\) satisfies (1.3), we have

Then by (4.1) we get

The authors are very grateful to the referees for their careful reading, comments, and suggestions, which helped us improve the presentation of this paper. The research of A Akbulut was partially supported by a grant of Ahi Evran University Scientific Research Projects PYO.FEN.4003.13.004 and PYO.FEN.4001.14.006. The research of Z Safarov was partially supported by a grant of Presidium Azerbaijan National Academy of Science 2015.

Authors and Affiliations

1. Department of Mathematics, Ahi Evran University, Kirsehir, Turkey

   Ali Akbulut

2. Institute of Mathematics and Mechanics of NASA, Baku, 1141, Azerbaijan

   Vugar H Hamzayev & Zaman V Safarov

3. Nakhchivan Teacher-Training Institute, Nakhchivan, Azerbaijan

   Vugar H Hamzayev

Corresponding author

Correspondence to Ali Akbulut.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

This work was carried out in collaboration between all authors. AA and VHH raised these interesting problems in the research. AA, VHH, and ZVS proved the theorems, interpreted the results, and wrote the article. All authors defined the research theme, and read and approved the manuscript.

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Reprints and permissions