A fourth-order elliptic Riemann type problem in \(\mathbb{R}^{3}\)

This article is concerned with a fourth-order elliptic equation i.e., \((\Delta^{2}-\kappa^{2}\Delta)[u]=0\) (\(\kappa>0\)) coupled by Riemann boundary value conditions in Clifford analysis. In the framework of a Clifford algebra \(\operatorname{Cl}(V_{3,3})\), we obtain factorizations of the fourth-order elliptic equation and construct the explicit expressions of higher-order kernel functions. Some integral representation formulas and properties of the null solution of the fourth-order elliptic equations in Clifford analysis are presented. Based on these integral representation formulas, the boundary behavior of some singular integral operators, and the Clifford analytic approach, we prove that the fourth-order elliptic Riemann type problem in \(\mathbb{R}^{3}\) is solvable. The explicit representation formula of the solution is also established.

Fourth-order elliptic equations have become a very important and useful area of mathematics over the last few decades, which is caused both by the intensive development of the theory of partial differential equations and their applications in various fields of physics and engineering such as theory of elasticity, micro-electro-mechanical systems, bi-harmonic systems, and so on. We refer to [1–10]. Recently the fourth-order elliptic equations

arise in the modeling of micro-electro-mechanical systems; see [5, 6]. The equations combining bi-harmonic equations with harmonic equations can be rewritten as

with \(\kappa=\sqrt{\frac{T}{B}}\).

The Riemann type problem is one of the famous problems in complex analysis and Clifford analysis; see [2–4, 11–23]. It is natural and important to study fourth-order elliptic equations coupled by the Riemann boundary conditions in \(\mathbb{R}^{n}\) (\(n\geq3\)). In general, two methods are used to deal with higher-order boundary value problems. One approach is to transform the boundary value problems for k-regular functions and poly-harmonic functions into equivalent boundary value problems for regular functions in Clifford analysis by the Almansi type decomposition theorem [15]. The other is to make use of higher-order integral representation formulas and a Clifford algebra approach [3, 4, 10]. Obviously, the first method fails to solve a system of the fourth-order elliptic equation i.e., \((\Delta^{2}-\kappa^{2}\Delta)u=0\), coupled by the Riemann boundary conditions. Using the second method, we need to investigate factorizations of the fourth-order elliptic operator in the framework of a Clifford algebra. Furthermore, we will construct higher-order kernels. The key idea is to choose an appropriate framework of the Clifford algebra. A lot of boundary value problems for some functions with the Clifford algebra \(\operatorname{Cl}(V_{n,0})\) (\(n\geq3\)) have been studied; for example, see [2, 3, 11–13, 15, 16, 24]. However, we fail to obtain factorizations of the fourth-order elliptic equation \((\Delta^{2}-\kappa^{2}\Delta)u=0\) (\(\kappa>0\)) using the Clifford algebra \(\operatorname{Cl}(V_{n,0})\). In this article, using a Clifford algebra \(\operatorname{Cl}(V_{3,3})\), we get the decomposition of the fourth-order elliptic operator i.e., \((\Delta^{2}-\kappa^{2}\Delta)\), and, moreover, construct higher-order kernel functions, which is different from [17, 25] due to choosing different Clifford algebra.

The article is organized as follows. In Section 2, we recall some basic facts about the Clifford analysis needed in the sequel. In Section 3, in the framework of the Clifford algebra \(\operatorname{Cl}(V_{3,3})\), we construct the explicit expressions of the kernel functions and obtain some integral representation formulas, we study some properties of null solutions for the fourth-order elliptic equations \((\Delta^{2}-\kappa^{2}\Delta)u=0\), for instance, the mean value formula, the Painlevé principle, and so on. Section 4, on the basis of the above results, considers a Riemann boundary value problem for the fourth-order elliptic equation.

Let \(V_{3,3}\) be an 3-dimensional real linear space with basis \(\{ e_{1}, e_{2}, e_{3}\}\), \(\operatorname{Cl}(V_{3,3})\) be the Clifford algebra over \(V_{3,3}\) and the 8-dimensional real linear space with basis

where N stands for the set \(\{1, 2, 3\}\) and \(\mathcal{P}N\) denotes the family of all order-preserving subsets of N in the above way. We denote \(e_{\emptyset}\) by \(e_{0}\) and \(e_{A}\) by \(e_{l_{1}\cdots l_{r}}\) for \(A=\{l_{1},\ldots,l_{r}\}\in \mathcal{P}N\). The product on \(\operatorname{Cl}(V_{3,3})\) is defined by

where \(n(A)\) is the cardinal number of the set A, the number \(P(A,B)=\sum_{j\in B}P(A,j)\), \(P(A,j)=n\{i,i\in A,i>j\}\), the symmetric difference set \(A\Delta B\) is order-preserving in the above way, and \(\lambda_{A}\in\mathbb{R}\) is the coefficient of the \(e_{A}\)-component of the Clifford number λ. It follows from the multiplication rule above that \(e_{0}\) is the identity element written now as 1 and, in particular, \(e_{i}e_{j}+e_{j}e_{i}=2\delta_{ij}\), \(i, j=1,2,3\). Thus \(\operatorname{Cl}(V_{3,3})\) is a real linear, associative, but non-commutative algebra. An involution is defined by

The norm of λ is defined by \(\|\lambda\|=(\sum_{A\in \mathcal{P}N}|\lambda_{A}|^{2})^{\frac{1}{2}}\). Throughout this article, suppose that Ω is an open bounded non-empty subset of \(\mathbb{R}^{3}\) with a Lyapunov boundary ∂Ω, we denote \(\Omega^{+}=\Omega\), \(\Omega^{-}=\mathbb{R}^{3}\setminus\overline{\Omega}\). We now introduce the Dirac operator \(D=\sum_{i=1}^{3}e_{i}\frac {\partial}{\partial x_{i}}\). In particular, we have \(DD=\Delta\) where Δ is the Laplacian over \(\mathbb{R}^{3}\). A function \(u:\Omega\mapsto \operatorname{Cl}(V_{3,3})\) is said to be left monogenic if it satisfies the equation \(D[u](\mathbf{x})=0\) for each \(\mathbf{x}\in\Omega\). A similar definition can be given for right monogenic functions.

Denote

and

where \((l_{1},\ldots,l_{p})\in\{2,3\}^{p}\), the sum is taken over all permutations with repetition of the sequence \((l_{1},\ldots,l_{p})\). In particular we define \(V_{l_{1},\ldots,l_{p}}(\mathbf{x})=1\) for \(p=0\) and \(V_{l_{1},\ldots,l_{p}}(\mathbf{x})=0\) for \(p<0\).

Lemma 2.1

[26]

Let \(C_{j,p}\) and \(V_{l_{1},\ldots,l_{p}}(\mathbf{x})\) be as above, then for \(j\in\mathbf{N}^{*}\),

where \(\mathbf{x}=\sum_{i=1}^{3}x_{i}e_{i}\),

In the following, we define

Lemma 2.2

[4, 27]

Let \(D[u]=0\) in \(\mathbb{R}^{3}\) and \(\liminf_{r\rightarrow\infty }\frac{M(r, u)}{r^{m}}=L<\infty\), \(m\in\mathbf{N}^{*}\). Then

For more information as regards the properties of Dirac operators and left monogenic functions can be found in [2, 3, 27–29].

The fourth-order elliptic partial differential operator \(\Delta ^{2}-\kappa^{2}\Delta\), for \(\kappa>0\), corresponds to the fourth-order elliptic equation:

Using the multiplication rule on the Clifford algebra \(\operatorname{Cl}(V_{3,3})\), equation (3.1) may also be written as

where \(L_{\kappa}=D+\kappa\) and \(L_{-\kappa}=D-\kappa\).

Lemma 3.1

[7, 8]

Let

Then the kernel function \(E(\kappa, \mathbf{x})\) is the fundamental solution to (3.1) in \(\mathbb{R}^{3}\).

Let

and

where \(\kappa>0\), \(\mathbf{x}\in\mathbb{R}^{3}\setminus\{0\}\).

Lemma 3.2

Let \(H_{i}(\kappa, \mathbf{x})\) and \(E_{i}(\kappa, \mathbf{x})\) be as in (3.3) and (3.4), \(i=1,2,3,4\). Then

and

here \(\kappa>0\), \(\mathbf{x}\in\mathbb{R}^{3}\setminus\{0\}\).

Remark 3.3

Let

and

When \(H_{3}^{*}(\kappa, \mathbf{x})\), \(E_{1}^{*}(\kappa, \mathbf{x})\) replace \(H_{3}(\kappa, \mathbf{x})\), \(E_{1}(\kappa, \mathbf{x})\) in (3.3), (3.4), respectively, we have the following results:

Let Ω be an open non-empty subset of \(\mathbb{R}^{3}\) with a Lyapunov boundary, \(u(\mathbf{x})=\sum_{A}e_{A}u_{A}(\mathbf{x})\), where \(u_{A}(\mathbf{x})\) are real functions. \(u(\mathbf{x})\) is called a Hölder continuous function on Ω̅ if the following condition is satisfied:

where, for any \(\mathbf{x}_{1}, \mathbf{x}_{2}\in\overline{\Omega}\), \(\mathbf{x}_{1}\neq\mathbf{x}_{2}\), \(0<\alpha\leq1\), C is a positive constant independent of \(\mathbf{x}_{1}\), \(\mathbf{x}_{2}\).

Lemma 3.4

Let \(f, g\in C^{1}(\Omega, \operatorname{Cl}(V_{3,3}))\cap C(\overline{\Omega}, \operatorname{Cl}(V_{3,3}))\). Then

where dV denotes Lebesgue volume measure, dσ stands for \(\operatorname{Cl}(V_{3,3})\)-valued 2-differential form.

Proof

From Stokes’ theorem in Clifford analysis in [29], the results can be directly proved. □

Theorem 3.5

Suppose that Ω is an open bounded non-empty subset of \(\mathbb {R}^{3}\) with a Lyapunov boundary ∂Ω, \(u\in C^{4}(\Omega, \operatorname{Cl}(V_{3,3}))\cap C^{3}(\overline{\Omega}, \operatorname{Cl}(V_{3,3}))\). Then

where \(H_{i}(\kappa, \mathbf{y}-\mathbf{x})\) (\(i=1,2,3,4\)) are as in (3.3).

Proof

Let \(\mathbf{x}\in\mathbb{R}^{3}\setminus\overline{\Omega}\). Using Lemma 3.4 and Lemma 3.2, we get

Assume

Applying Lemma 3.4 and Lemma 3.2 once again, we continue to calculate the integral \(I_{1}\) and get

From (3.9) and (3.10), in this case, the result follows.

Now, let \(\mathbf{x}\in\Omega\) and take \(r>0\) such that \(B(\mathbf{x}, r)\subset\Omega\). Invoking the previous case, we may write

Here we take the limits for \(r\rightarrow0\). As regards the weak singularity of \(H_{4}(\kappa, \mathbf{y}-\mathbf{x})\), it follows that

Furthermore we write

We denote

Applying the Stokes formula and the Lebesgue differentiation theorem, we have

Combining (3.11) with (3.12)-(3.14), we get the desired result. □

Theorem 3.6

Suppose that Ω is an open bounded non-empty subset of \(\mathbb {R}^{3}\) with a Lyapunov boundary ∂Ω, \(u\in C^{4}(\Omega, \operatorname{Cl}(V_{3,3}))\cap C^{3}(\overline{\Omega}, \operatorname{Cl}(V_{3,3}))\). Then

where \(E_{i}(\kappa, \mathbf{y}-\mathbf{x})\) (\(i=1,2,3,4\)) are as in (3.4).

Proof

The result can be similarly proved to Theorem 3.5. □

Applying Theorems 3.5 and 3.6, we directly have the following results.

Theorem 3.7

Suppose that Ω is an open bounded non-empty subset of \(\mathbb {R}^{3}\) with a Lyapunov boundary ∂Ω, \(u\in C^{4}(\Omega, \operatorname{Cl}(V_{3,3}))\cap C^{3}(\overline{\Omega}, \operatorname{Cl}(V_{3,3}))\), and \((\Delta^{2}-\kappa^{2}\Delta)[u]=0\) in Ω. Then

where \(H_{i}(\kappa, \mathbf{y}-\mathbf{x})\) (\(i=1,2,3,4\)) are as in (3.3).

Theorem 3.8

Suppose that Ω is an open bounded non-empty subset of \(\mathbb {R}^{3}\) with a Lyapunov boundary ∂Ω, \(u\in C^{4}(\Omega, \operatorname{Cl}(V_{3,3}))\cap C^{3}(\overline{\Omega}, \operatorname{Cl}(V_{3,3}))\), and \((\Delta^{2}-\kappa^{2}\Delta)[u]=0\) in Ω. Then

where \(E_{i}(\kappa, \mathbf{y}-\mathbf{x})\) (\(i=1,2,3,4\)) are as in (3.4).

In this article, as usual dS denotes the Lebesgue surface measure. Using Theorem 3.7 or 3.8, we have the following result.

Corollary 3.9

Suppose that \((\Delta^{2}-\kappa^{2}\Delta)[u](\mathbf{x})=0\) in \(\mathbb{R}^{3}\). Then

Proof

For arbitrary \(\mathbf{x}\in\mathbb{R}^{3}\), Theorem 3.7 and Stokes’ formula imply

Using the mean value formula for harmonic functions and the condition \((\Delta^{2}-\kappa^{2}\Delta)[u]=0\), from (3.18), we have

Thus the result follows. □

Theorem 3.10

Suppose that \((\Delta^{2}-\kappa^{2}\Delta)[u]=0\) in \(\mathbb{R}^{3}\) and \(\lim_{r\rightarrow\infty}\frac{\Lambda(r,u)}{r^{m}}=l<\infty\), \(m\in\mathbf{N}^{*}\). Then

Proof

For arbitrary \(\mathbf{x}\in\mathbb{R}^{3}\), by Corollary 3.9, we have

Taking \(R=\|\mathbf{x}\|\) in (3.21), we obtain

Denoting \(\|\mathbf{x}\|=r\), we get from (3.22)

The inequality (3.23) can be rewritten as

In view of (3.23) and \(\lim_{r\rightarrow\infty}\frac {\Lambda(r,u)}{r^{m}}=l<\infty\), when \(r\rightarrow\infty\), we get \(\Delta[u](\infty)=0\).

Using Lemma 3.13 in [19] and \((\Delta-\kappa^{2})\Delta[u](\mathbf{x})=0\), we obtain

and

From (3.25) and (3.26), we further obtain \(D^{3}[u](\infty)=0\).

We finally verify the remaining of the result of the theorem. For all \(\mathbf{x}\in\mathbb{R}^{3}\), from Theorem 3.7, Lemma 3.2, Remark 3.3, and Stokes’ formula it follows that

Taking \(R=\|\mathbf{x}\|\) in (3.27), in view of the maximum principle of the modified Helmholtz equation in [7, 18], it immediately follows that

Denoting \(\|\mathbf{x}\|=r\), we conclude from (3.28)

Then by (3.29), we have

Applying the maximum principle of the modified Helmholtz equation and the condition \(\lim_{r\rightarrow\infty}\frac{\Lambda(r,u)}{r^{m}}=l<\infty\), we have \(\liminf_{r\rightarrow\infty}\frac {M(r,D[u])}{r^{m-1}}<\infty\). The proof is completed. □

Next, denote some integral operators as follows:

where \(H_{i}(\kappa, \mathbf{y}-\mathbf{x})\) (\(i=1,2,3,4\)) are as in (3.3) and the above singular integral is taken in the principal sense.

Lemma 3.11

Let Ω be an open, bounded non-empty subset of \(\mathbb{R}^{3}\) with Lyapunov boundary ∂Ω, \(u(\mathbf{x})\in H^{\alpha}(\partial\Omega, \operatorname{Cl}(V_{3,3}))\), \(0<\alpha \leq1\). Then, for \(\mathbf{x}\in\partial\Omega\),

Proof

Applying the Plemelj formulas with parameter (Theorem 2.3 in [10]), the result follows. □

In the following, we denote

where \(\Omega=\Omega^{+}\) and \(\Omega^{-}=\mathbb{R}^{3}\setminus \overline{\Omega}\).

Theorem 3.12

Assume that Ω is an open, bounded non-empty subset of \(\mathbb {R}^{3}\) with a Lyapunov boundary ∂Ω, \(u\in C^{4}(\Omega, \operatorname{Cl}(V_{3,3}))\cap C^{3}(\overline{\Omega}, \operatorname{Cl}(V_{3,3}))\), \(u\in C^{4}(\Omega^{-}, \operatorname{Cl}(V_{3,3}))\cap C^{3}(\overline{\Omega} ^{-}, \operatorname{Cl}(V_{3,3}))\) and \(u(\mathbf{x})\) satisfies the following conditions:

where \(0<\alpha_{i}\leq1\), \(i=1,2,3,4\), then \((\Delta^{2}-\kappa ^{2}\Delta)[u]=0\) in \(\mathbb{R}^{3}\).

Proof

We only need to prove that for \(\forall\mathbf{x}_{0}\in\partial\Omega \), \((\Delta^{2}-\kappa^{2}\Delta)[u]=0\). Taking a constant \(r>0\), \(B(\mathbf{x}_{0}, r)\) is an open ball with the center at \(\mathbf {x}_{0}\) and radius r such that \(\Omega\subset B(\mathbf{x}_{0}, r)\). It is clear that \(\partial\Omega \cup\partial B(\mathbf{x}_{0}, r)\) is a Lyapunov boundary.

Let

here \(\mathbf{x}\in\partial\Omega\). In view of Theorem 3.7, it follows that

Combining (3.36) with (3.37) and using Lemma 3.11, we obtain

From (3.38) and (3.39), we derive

Therefore \(\Delta(\Delta-\kappa^{2})[u](\mathbf{x}_{0})=0\), the result follows. □

Theorem 3.13

Let Ω be an open bounded non-empty subset of \(\mathbb{R}^{3}\) with Lyapunov boundary ∂Ω, \(u\in C^{4}(\Omega^{-}, \operatorname{Cl}(V_{3,3}))\cap C^{3}(\overline{\Omega}^{-}, \operatorname{Cl}(V_{3,3}))\), \((\Delta^{2}-\kappa^{2}\Delta)[u]=0\) in \(\Omega^{-}\), and

where \(0<\alpha_{i}\leq1\), \(i=1, 2, 3, 4\). Then

Proof

For \(\mathbf{y}\in\partial\Omega\), let

For \(\mathbf{x}\in\mathbb{R}^{3}\setminus\partial\Omega\), we get

and

in view of Lemma 3.2, it is easy to check that \((\Delta ^{2}-\kappa^{2}\Delta)[\widetilde{F}]=0\) in \(\mathbb{R}^{3}\setminus\partial\Omega\), combining Lemma 3.11, we get

Thus \((\Delta^{2}-\kappa^{2}\Delta)[\widetilde{F}]=0\) in \(\mathbb{R}^{3}\) where we use Theorem 3.12. Obviously, \(\lim_{r\rightarrow\infty}\frac{\Lambda(r,\widetilde{F}(\mathbf {x}))}{r^{m}}=l<\infty\), using Theorem 3.10, we arrive at

For \(\mathbf{x}\in\Omega^{-}\),

Equations (3.41) and (3.42) imply that the result holds. □

In this section we will find solutions to

where A, B, C, D are invertible Clifford constants and \(g_{1}(\mathbf{x}), g_{2}(\mathbf{x}), g_{3}(\mathbf{x}), g_{4}(\mathbf{x})\in H^{\alpha}(\partial\Omega, \operatorname{Cl}(V_{3,3}))\), \(0<\alpha\leq1\), \(\kappa>0\).

Theorem 4.1

The Riemann type problem (4.1) is solvable and the solution can be written as

where

and

Proof

Let \(u(\mathbf{x})\) be the solution of (4.1) for \(\mathbf {x}\in\mathbb{R}^{3}\setminus\partial\Omega\), we denote \(\omega(\mathbf{x})=L_{\kappa}\Delta[u](\mathbf{x})\). Then

In view of Theorem 3.13, \((\Delta^{2}-\kappa^{2}\Delta )[u](\mathbf{x})=L_{-\kappa}L_{\kappa}\Delta[u](\mathbf{x})=0\), and \(\lim_{r\rightarrow\infty}\frac{\Lambda(r,u)}{r^{m}}=l<\infty \), we have

Let

It is easy to check that

If we denote

and use boundary value condition

we conclude

here \(\tilde{g}_{3}(\mathbf{x})\in H^{\tilde{\alpha}}(\partial \Omega, \operatorname{Cl}(V_{3,3}))\), \(0<\tilde{\alpha}\leq1\) is taken from (4.7). It follows that \(\Theta(\infty)=0\) from Theorem 3.13. Using (4.12), we get the representation formula

Analogously, we find with \(u_{2}(\mathbf{x})\) from (4.4) that

Denoting \(D[u]-D[u_{1}]-D[u_{2}]\triangleq\Xi\), where \(\mathbf{x}\in \mathbb{R}^{3}\setminus\partial\Omega\) and using the boundary value condition

it follows that

where \(\tilde{g}_{2}(\mathbf{x})\in H^{\tilde{\alpha}}(\partial \Omega, \operatorname{Cl}(V_{3,3}))\), \(0<\tilde{\alpha}\leq1\) is taken from (4.8). Again applying Theorem 3.13, we have \(\liminf_{r\rightarrow\infty}\frac{M(r,\Xi)}{r^{m-1}}<\infty\). In view of (4.17) and Lemma 2.2, we obtain

Finally, we use

We arrive at

Defining

According to the boundary value condition

we get

where \(\tilde{g}_{1}(\mathbf{x})\in H^{\tilde{\alpha}}(\partial \Omega, \operatorname{Cl}(V_{3,3}))\), \(0<\tilde{\alpha}\leq1\), is as in (4.7). It is clear that \(\liminf_{r\rightarrow\infty}\frac{M(r,\Upsilon )}{r^{m}}<\infty\). Using Lemma 2.2, we get

On the other hand, we can directly prove that (4.2) is the solution of (4.1). The proof is completed. □

Research was supported by NNSF of China (Nos. 11401287 and 11301248), the AMEP and DYSP of Linyi University.

Authors and Affiliations

1. Department of Mathematics, Linyi University, Linyi, Shandong, 276005, P.R. China

   Longfei Gu

Corresponding author

Correspondence to Longfei Gu.

Competing interests

The author declares that they have no competing interests.

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