Regularity theory on A-harmonic system and A-Dirac system

In this paper, we show the regularity theory on an A-harmonic system and an A-Dirac system. By the method of the removability theorem, we explain how an A-harmonic system arises from an A-Dirac system and establish that an A-harmonic system is in fact the real part of the corresponding A-Dirac system.

In this paper, we consider the regularity theory on an A-Dirac system,

and an A-harmonic system,

Here Ω is a bounded domain in $R^n$ ($n\ge 2$), $A(x,u,\mathrm{\nabla }u)$ and $f(x,u,\mathrm{\nabla }u)$ are measurable functions defined on $\mathrm{\Omega }\times R^n\times R^{nN}$, N is an integer with $N>1$, $u:\mathrm{\Omega }\to R^n$ is a vector valued function. Furthermore, $A(x,u,\mathrm{\nabla }u)$ and $f(x,u,\mathrm{\nabla }u)$ satisfy the following structural conditions with $m>2$:

(H1) $A(x,u,p)$ are differentiable functions in p and there exists a constant $C>0$ such that

(H2) $A(x,u,p)$ are uniformly strongly elliptic, that is, for some $\lambda >0$ we have

(H3) There exist $\beta \in (0,1)$ and $K:[0,\mathrm{\infty })\mapsto [0,\mathrm{\infty })$ monotone nondecreasing such that

for all $x,\tilde{x}\in \mathrm{\Omega }$, $u,\tilde{u}\in R^n$, and $p\in R^{nN}$. Without loss of generality, we take $K\ge 1$.

(H4) There exist constants $C_1$ and $C_2$ such that

(H1) and (H2) imply

for all $x\in \mathrm{\Omega }$, $u\in R^n$ and $p,\xi \in R^{nN}$, where $\lambda >0$ is a constant.

Definition 1.1 We say that a function $u\in W_{\mathrm{loc}}^{1,m}(\mathrm{\Omega })\cap L^{\mathrm{\infty }}(\mathrm{\Omega })$ is a weak solution to (1.2), if the equality

holds for all $\varphi \in W_0^{1,m}(\mathrm{\Omega })$ with compact support.

In this paper, we assume that the solutions of the A-harmonic system (1.1) and the A-Dirac system (1.2) exist [1] and establish the regularity result directly. In other words, the main purpose of this paper is to show the regularity theory on an A-harmonic system and the corresponding A-Dirac system. It means that we should know the properties of an A-harmonic operator and an A-Dirac operator. This main context will be stated in Section 2. Further discussion can be found in [2–10] and the references therein.

In order to prove the main result, we also need a suitable Caccioppoli estimation (see Theorem 3.1). Then by the technique of removable singularities, we can find that solutions to an A-harmonic system satisfying a Lipschitz condition or in the case of a bounded mean oscillation can be extended to Clifford valued solutions to the corresponding A-Dirac system.

The technique of removable singularities was used in [2] to remove singularities for monogenic functions with modulus of continuity $\omega (\mathit{r})$, where the sets $r^n\omega (r)$ and Hausdorff measure are removable. Kaufman and Wu [11] used the method in the case of Hölder continuous analytic functions. In fact, under a certain geometric condition related to the Minkowski dimension, sets can be removable for A-harmonic functions in Hölder and bounded mean oscillation classes [12]. Even in the case of Hölder continuity, a precise removable sets condition was stated [13]. In [7], the author showed that under a certain oscillation condition, sets satisfying a generalized Minkowski-type inequality were removable for solutions to the A-Dirac system. The general result can be found in [14].

Motivated by these facts, one ask: Does a similar result hold for the more general case of the systems (1.1) and (1.2)? We will answer this question in this paper and obtain the following result.

Theorem 1.2 Let E be a relatively closed subset of Ω. Suppose that $u\in L_{\mathrm{loc}}^m(\mathrm{\Omega })\cap L^{\mathrm{\infty }}(\mathrm{\Omega })$ has distributional first derivatives in Ω, u is a solution to the scalar part of A-Dirac system (1.1) under the structure conditions (H1)-(H4) in $\mathrm{\Omega }\setminus E$, and u is of the type of an $m,k$-oscillation in $\mathrm{\Omega }\setminus E$. If for each compact subset K of E

then u extends to a solution of the A-Dirac system in Ω.

In this section, we would introduce the A-Dirac system. Thus the definition of the A-Dirac operator is necessary. We first present the definitions and notations as regards the Clifford algebra at first [7].

We write ${\mathcal{U}}_n$ for the real universal Clifford algebra over $R^n$. The Clifford algebra is generated over R by the basis of the reduced products

where $\{e_1,e_2,\dots ,e_n\}$ is an orthonormal basis of $R^n$ with the relation $e_i{e}_j+e_j{e}_i=-2{\delta }_{ij}$. We write $e_0$ for the identity. The dimension of ${\mathcal{U}}_n$ is $2^n$. We have an increasing tower $R\subset C\subset H\subset {\mathcal{U}}_3\subset \cdots$ . The Clifford algebra ${\mathcal{U}}_n$ is a graded algebra as ${\mathcal{U}}_n={⨁}_l{\mathcal{U}}_n^l$, where ${\mathcal{U}}_n^l$ are those elements whose reduced Clifford products have length l.

For $A\in {\mathcal{U}}_n$, $Sc(A)$ denotes the scalar part of A, that is, the coefficient of the element $e_0$.

Throughout this paper, $\mathrm{\Omega }\subset R^n$ is a connected and open set with boundary ∂ Ω. A Clifford-valued function $u:\mathrm{\Omega }\to {\mathcal{U}}_n$ can be written as $u={\sum }_{\alpha }{u}_{\alpha }{e}_{\alpha }$, where each $u_{\alpha }$ is real-valued and $e_{\alpha }$ are reduced products. The norm used here is given by $|{\sum }_{\alpha }{u}_{\alpha }{e}_{\alpha }|={({\sum }_{\alpha }{u}_{\alpha }^2)}^{\frac{1}{2}}$, which is sub-multiplicative, $|AB|\le C|A||B|$.

The Dirac operator defined here is

Also $D^2=-\mathrm{△}$. Here △ is Laplace operator.

Throughout, Q is a cube in Ω with volume $|Q|$. We write σQ for the cube with the same center as Q and with side length σ times that of Q. For $q>0$, we write $L^q(\mathrm{\Omega },{\mathcal{U}}_n)$ for the space of Clifford-valued functions in Ω whose coefficients belong to the usual $L^q(\mathrm{\Omega })$ space. Also, $W^{1,m}(\mathrm{\Omega },{\mathcal{U}}_n)$ is the space of Clifford valued functions in Ω whose coefficients as well as their first distributional derivatives are in $L^q(\mathrm{\Omega })$. We also write $L_{\mathrm{loc}}^q(\mathrm{\Omega },{\mathcal{U}}_n)$ for $\bigcap L^q({\mathrm{\Omega }}^{\prime },{\mathcal{U}}_n)$, where the intersection is over all ${\mathrm{\Omega }}^{\prime }$ compactly contained in Ω. We similarly write $W_{\mathrm{loc}}^{1,m}(\mathrm{\Omega },{\mathcal{U}}_n)$. Moreover, we write ${\mathcal{M}}_{\mathrm{\Omega }}=\{u:\mathrm{\Omega }\to {\mathcal{U}}_n|Du=0\}$ for the space of monogenic functions in Ω.

Furthermore, we define the Dirac Sobolev space

The local space $W_{\mathrm{loc}}^{D,m}$ is similarly defined. Notice that if u is monogenic, then $u\in L^m(\mathrm{\Omega })$ if and only if $u\in W^{D,m}(\mathrm{\Omega })$. Also it is immediate that $W^{1,m}(\mathrm{\Omega })\subset W^{D,m}(\mathrm{\Omega })$.

With those definitions and notations and also of the A-Dirac operator, we define the linear isomorphism $\theta :R^n\to {\mathcal{U}}_n^1$ by

For $x,y\in R^n$, Du is defined by $\theta (\mathrm{\nabla }\varphi )=D\varphi$ for a real-valued function ϕ, and we have

Here $\tilde{A}(x,\xi ,\eta ):\mathrm{\Omega }\times {\mathcal{U}}_1\times {\mathcal{U}}_n\to {\mathcal{U}}_n$ is defined by

which means that (1.5) is equivalent to

For the Clifford conjugation $\overline{(e_{j1}\cdots e_{jl})}={(-1)}^l{e}_{jl}\cdots e_{j1}$, we define a Clifford-valued inner product as $\overline{\alpha }\beta$. Moreover, the scalar part of this Clifford inner product $Sc(\overline{\alpha }\beta )$ is the usual inner product $〈\alpha ,\beta 〉$ in $R^{2^n}$, when α and β are identified as vectors.

For convenience, we replace $\tilde{A}$ with A and recast the structure systems above and define the operator:

where A preserves the grading of the Clifford algebra, $x\to A(x,\xi ,\eta )$ is measurable for all ξ, η, and $\xi \to A(x,\xi ,\eta )$, $\eta \to A(x,\xi ,\eta )$ are continuous for a.e. $x\in \mathrm{\Omega }$.

Definition 2.1 A Clifford valued function $u\in W_{\mathrm{loc}}^{D,m}(\mathrm{\Omega },{\mathcal{U}}_n^k)\cap L^{\mathrm{\infty }}(\mathrm{\Omega },{\mathcal{U}}_n^k)$, for $k=0,1,\dots ,n$, is a weak solution to system (1.1) under conditions (H1)-(H4). If for all $\varphi \in W_0^{1,m}(\mathrm{\Omega },{\mathcal{U}}_n^k)$, then we have

In this section, we will establish the main results. At first, a suitable Caccioppoli estimate [7, 15] for solutions to (2.10) is necessary.

Theorem 3.1 Let u be weak solutions to the scalar part of system (1.1) with $\lambda >2C_{1}M$ and where (H1)-(H4) are satisfied. Then for every $x_0\in \mathrm{\Omega }$, $u_0\in {\mathcal{U}}_1^k$, $p_0\in {\mathcal{U}}_n^k$, and arbitrary $\sigma >1$ we have

where $P=u(x)-u_0+p_0(x-x_0)$ and

Proof Denote $u(x)-u_0-p_0(x-x_0)$ by $v(x)$ and $0<{|Q|}^{\frac{1}{n}}<\sigma {|Q|}^{\frac{1}{n}}<min\{1,dist(x_0,\partial \mathrm{\Omega })\}$ for $\sigma >1$, consider a standard cut-off function $\eta \in C_0^{\mathrm{\infty }}(\sigma Q(x_0))$ satisfying $0\le \eta \le 1$, $|\mathrm{\nabla }\eta |<\frac{1}{{|Q|}^{1/n}}$, $\eta \equiv 1$ on $Q(x_0)$. Then $\phi ={\eta }^{2}v$ is admissible as a test-function, and we obtain

We further have

and

Adding these equations yields

where

after using (1.3), (H3), (H4).

For positive ε, to be fixed later, using Young’s inequality, we have

Using Young’s inequality twice in II, we have

and similarly we see

and

and for positive μ, to be fixed later, this yields

By (1.4), we obtain

Combining these estimates in (3.3) and noting that $K^2\le K^{\frac{2}{1-\beta }}$ (as $K\ge 1$), ${(\sigma |Q|)}^{\frac{2\beta }{(1-\beta )n}}\le {(\sigma |Q|)}^{\frac{2\beta }{n}}$ for $\sigma >1$, ${[{(1+|p_0|)}^{\frac{m}{2}}]}^{\frac{2}{1-\beta }}\ge {(1+|p_0|)}^{2(\frac{m}{2}+\beta )}$, and $4\le 4^{\frac{2}{1-\beta }}$, we can estimate

Define $\epsilon =\epsilon (\lambda ,m)$, $\mu =\mu (C_1,M,m,\lambda )$ small enough, we obtain

where $C=C(m,\lambda ,\beta ,M)$ and

Now let the domain of the left-hand side be Q, then we can get the right inequality immediately. □

In order to remove singularity of solutions to A-Dirac system, we also need the fact that real-valued functions satisfying various regularity properties. Thus we have the following.

Definition 3.2 [7]

Assume that $u\in L_{\mathrm{loc}}^1(\mathrm{\Omega },{\mathcal{U}}_n)$, $q>0$, and that $-\mathrm{\infty }<k<1$. We say that u is of the type of a $q,k$-oscillation in Ω when

If $q=1$ and $k=0$, then the inequality (3.4) is equivalent to the usual definition of the bounded mean oscillation; when $q=1$ and $0<k\le 1$, then the inequality (3.4) is equivalent to the usual local Lipschitz condition [16]. Further discussion of the inequality (3.4) can be found in [8, 17]. In these cases, the supremum is finite if we choose $u_Q$ to be the average value of the function u over the cube Q.

We remark that it follows from Hölder’s inequality that if $s\le q$ and if u is of the type of an $q,k$-oscillation, then u is of the type of an $s,k$-oscillation.

The following lemma shows that Definition 3.2 is independent of the expansion factor of the sphere.

Lemma 3.3 [7]

Suppose that $F\in L_{\mathrm{loc}}^1(\mathrm{\Omega },R)$, $F>0$ a.e., $r\in R$ and ${\sigma }_1,{\sigma }_2>1$. If

then

Then we proceed to prove the main result, Theorem 1.2.

Proof of Theorem 1.2 Let Q be a cube in the Whitney decomposition of $\mathrm{\Omega }\setminus E$. The decomposition consists of closed dyadic cubes with disjoint interiors which satisfy

1. (a)

   $\mathrm{\Omega }\setminus E={\bigcup }_{Q\in \mathcal{W}}Q$,

2. (b)

   ${|Q|}^{1/n}\le d(Q,\partial \mathrm{\Omega })\le 4{|Q|}^{1/n}$,

3. (c)

   $(1/4){|Q_1|}^{1/n}\le {|Q_2|}^{1/n}\le 4{|Q_1|}^{1/n}$ when $Q_1\cap Q_2$ is not empty.

Here $d(Q,\partial \mathrm{\Omega })$ is the Euclidean distance between Q and the boundary of Ω [18].

If $A\subset R^n$ and $r>0$, then we define the r-inflation of A as

Let Q be a cube in the Whitney decomposition of $\mathrm{\Omega }\setminus E$. Using the Caccioppoli estimate (3.1), we have

with (3.2)

where

and choose $|Q|$ small enough such that

By the definition of the $q,k$-oscillation condition, we have

Here $a=(n+mk-m)/n$. Since the problem is local (use a partition of unity), we show that (2.10) holds whenever $\varphi \in W_0^{1,m}(B(x_0,r))$ with $x_0\in E$ and $r>0$ sufficiently small. Choose $r=(1/5\sqrt{n})min\{1,d(x_0,\partial \mathrm{\Omega })\}$ and let $K=E\cap \overline{B}(x_0,4r)$. Then K is a compact subset of E. Also let $W_0$ be those cubes in the Whitney decomposition of $\mathrm{\Omega }\setminus E$ which meet $B=B(x_0,r)$. Notice that each cube $Q\in W_0$ lies in $\mathrm{\Omega }\setminus K$. Let $\gamma =m(k-1)-k$. First, since $\gamma \ge -1$, from [12] we have $m(K)=m(E)=0$. Also since $na-n\ge \gamma$, using (1.6) and (3.8), we obtain

Hence $u\in W_{\mathrm{loc}}^{D,m}(\mathrm{\Omega })$.

Next let $B=B(x_0,r)$ and assume that $\psi \in C_0^{\mathrm{\infty }}(B)$. Also let $W_j$, $j=1,2,\dots$ , be those cubes $Q\in W_0$ with $l(Q)\le 2^{-j}$.

Consider the scalar functions

Thus each ${\varphi }_j$, $j=1,2,\dots$ , is Lipschitz, equal to 1 on K and as such $\psi (1-{\varphi }_j)\in W^{1,m}(B\setminus E)$ with compact support. Hence

Let

Since u is a solution in $B\setminus E$, $J_1=0$.

Next we estimate $J_2$ as

Noting that there exists a constant C such that $|\psi |\le C<\mathrm{\infty }$,

Recalling that ${|Q|}^{\frac{\beta }{n}}K(t)\le 1$, we have