2.1 Notation, assumptions

For vectors $a,\,b\in \mathbb{R} ^3$, we define the scalar product $\langle a,\,b\rangle :=\sum _{i=1}^3 a_ib_i$, the Euclidean norm $|a|^2:=\langle a,\,a\rangle$ and the dyadic product $a\otimes b=(a_ib_j)_{i,j=1}^3\in \mathbb{R} ^{3\times 3}$, where $\mathbb{R} ^{3\times 3}$ will denote the set of real $3\times 3$ matrices. For matrices $P,\,Q\in \mathbb{R} ^{3\times 3}$, we define the standard Euclidean scalar product $\langle P,\,Q\rangle :=\sum _{i=1}^3\sum _{j=1}^3 P_{ij}Q_{ij}$ and the Frobenius-norm $\|P\|^2:=\langle P,\,P\rangle$. $P^T\in \mathbb{R} ^{3\times 3}$ denotes the transposition of the matrix $P\in \mathbb{R} ^{3\times 3}$ and for $P\in \mathbb{R} ^{3\times 3}$, the symmetric part of $P$ will be denoted by $\operatorname {sym} P={1}/{2}(P+P^T)\in \operatorname {Sym}(3)$.

Let $\Omega \subset \mathbb{R} ^3$ be a bounded domain. As a minimal requirement, we assume in this paper that the boundary $\partial \Omega$ is Lipschitz continuous, meaning that it can locally be described as the graph of a Lipschitz continuous function, see [Reference Grisvard14] for a precise definition. In a similar spirit we speak of $C^1$ or $C^{1,1}$-regular boundaries. For a function $u=(u^1,\,u^2,\,u^3)^T:\Omega \to \mathbb{R} ^3$, the differential $\mathrm {D} u$ is given by

\[ \mathrm{D} u =\begin{pmatrix} \mathrm{D} u^1\\ \mathrm{D} u^2\\ \mathrm{D} u^3 \end{pmatrix} \in \mathbb{R}^{3\times 3}, \]

with $(\mathrm {D} u^k)_{l}= \partial _{x_l} u^k$ for $1\leq k\leq 3$ and $1\leq \ell \leq 3$ and with $\mathrm {D} u^k\in \mathbb{R} ^{1\times 3}$. For a vector field $w:\Omega \to \mathbb{R} ^3$, the divergence and the curl are given as

\[ \operatorname{div} w=\sum_{i=1}^ 3 w^{i}_{, x_i},\quad \operatorname{curl} w =\big(w^{3}_{,x_2}-w^{2}_{,x_3},w^{1}_{,x_3}-w^{3}_{,x_1},w^{1}_{,x_2}-w^{2}_{,x_1}\big). \]

For tensor fields $Q:\Omega \to \mathbb{R} ^{3\times 3}$, $\operatorname {Curl} Q$ and $\operatorname {Div} Q$ are defined row-wise:

\[ \operatorname{Curl} Q=\begin{pmatrix} \operatorname{curl} Q^1 \\ \operatorname{curl} Q^2\\ \operatorname{curl} Q^3 \end{pmatrix} \in \mathbb{R}^{3\times 3},\quad \text{ and } \operatorname{Div} Q=\begin{pmatrix} \operatorname{div} Q^1 \\ \operatorname{div} Q^2 \\ \operatorname{div} Q^3 \end{pmatrix}\in \mathbb{R}^3, \]

where $Q^i$ denotes the $i$-th row of $Q$. With these definitions, for $u:\Omega \to \mathbb{R} ^3$ we have consistently $\operatorname {Curl}\mathrm {D} u=0\in \mathbb{R} ^{3 \times 3}$.

The Sobolev spaces [Reference Adams and Fournier1, Reference Girault and Raviart11] used in this paper are

\begin{align*} & H^1(\Omega)=\{u\in L^2(\Omega)\, | \mathrm{D} u\in L^2(\Omega)\}\,, \quad \|u\|^2_{H^1(\Omega)}:=\|u\|^2_{L^2(\Omega)}+\|\mathrm{D} u\|^2_{L^2(\Omega)},\\ & H({\operatorname{curl}};\Omega)=\{v\in L^2(\Omega;\mathbb{R}^d)\, |\,\, \operatorname{curl} v\in L^2(\Omega)\},\quad\|v\|^2_{H({\rm curl};\Omega)}:=\|v\|^2_{L^2(\Omega)}\\& \quad +\|{\rm curl}\, v\|^2_{L^2(\Omega)},\\ & H(\operatorname{div};\Omega)=\{v\in L^2(\Omega;\mathbb{R}^d)\, |\,\, \operatorname{div} v\in L^2(\Omega)\},\quad \|v\|^2_{H({\operatorname{div}};\Omega)}:=\|v\|^2_{L^2(\Omega)}\\& \quad+\|\operatorname{div} v\|^2_{L^2(\Omega)}, \end{align*}

spaces for tensor valued functions are denoted by $H(\operatorname {Curl};\Omega )$ and $H(\operatorname {Div};\Omega )$. Moreover, $H_0^1(\Omega )$ is the completion of $C_0^{\infty }(\Omega )$ with respect to the $H^1$-norm and $H_0({\rm curl};\Omega )$ and $H_0(\operatorname {div};\Omega )$ are the completions of $C_0^{\infty }(\Omega )$ with respect to the $H(\operatorname {curl})$-norm and the $H(\operatorname {div})$-norm, respectively. By $H^{-1}(\Omega )$ we denote the dual of $H_0^1(\Omega )$. Finally we define

(2.1)\begin{equation} \begin{aligned} H(\operatorname{div},0;\Omega) & =\{u\in H(\operatorname{div};\Omega)\, |\,\, \operatorname{div} u=0\},\\ H(\operatorname{curl},0;\Omega) & =\{u\in H(\operatorname{curl};\Omega)\, |\,\, \operatorname{curl} u=0\} \end{aligned} \end{equation}

and set

(2.2)\begin{equation} \begin{aligned} H_0(\operatorname{div},0;\Omega) & =H_0(\operatorname{div};\Omega)\cap H(\operatorname{div},0;\Omega),\\ H_0(\operatorname{curl},0;\Omega) & =H_0(\operatorname{curl};\Omega)\cap H(\operatorname{curl},0;\Omega). \end{aligned} \end{equation}

Assumption A: We assume that the coefficient functions ${\mathbb {C}_{{\rm e}}},\,{\mathbb {C}_{{\rm micro}}}$ and ${\mathbb {L}}_{{\rm c}}$ in (1.2) are fourth order elasticity tensors from $C^{0,1}(\overline \Omega ;\operatorname{Lin} (\mathbb{R} ^{3\times 3};\mathbb{R} ^{3\times 3}))$ and are symmetric and positive definite in the following sense

1. (i) For every $\sigma,\,\tau \in \operatorname {Sym}(3)$, $\eta _1,\,\eta _2\in \mathbb{R} ^{3\times 3}$ and all $x\in \overline \Omega$:

   (2.3)\begin{align} \langle \mathbb{C}_e(x)\sigma,\tau\rangle = \langle \sigma,\mathbb{C}_e(x)\tau\rangle, \quad \langle \mathbb{C}_\text{micro}(x)\sigma,\tau\rangle & = \langle \sigma,\mathbb{C}_\text{micro}(x)\tau\rangle, \nonumber\\ \langle \mathbb{L}_c(x)\eta_1,\eta_2\rangle & = \langle\eta_1, \mathbb{L}_c(x)\eta_2\rangle. \end{align}

2. (ii) There exists positive constants $C_{\mathrm {e}}$, $C_{\mathrm {micro}}$ and $L_{\mathrm {c}}$ such that for all $x\in \overline \Omega$, $\sigma \in \operatorname {Sym}(3)$ and $\eta \in \mathbb{R} ^{3\times 3}$:

   (2.4)\begin{equation} \langle{\mathbb{C}_{{\rm e}}}(x)\sigma,\sigma\rangle\geq C_{\mathrm{e}}|\sigma|^2 ,\quad \langle{\mathbb{C}_{{\rm micro}}}(x)\sigma,\sigma\rangle\geq C_{\mathrm{micro}}|\sigma|^2\,,\quad\,\, \langle{\mathbb{L}}_{{\rm c}}(x)\eta,\eta\rangle\geq L_{\mathrm{c}}|\eta|^2. \end{equation}

2.2 Helmholtz decomposition, embeddings, elliptic regularity

Based on the results from Section 3.3 of the book [Reference Girault and Raviart11] (Corollary $3.4$), see also [Reference Bauer, Pauly and Schomburg4, Theorem 5.3], the following version of the Helmholtz decomposition will be used:

Theorem 2.1 Helmholtz decomposition

Let $\Omega \subset \mathbb{R} ^3$ be a bounded domain with a Lipschitz boundary. Then

\[ L^2(\Omega;\mathbb{R}^3)= \mathrm{D} H_0^1(\Omega)\oplus H(\operatorname{div},0;\Omega) \]

and hence, for every $p\in L^2(\Omega ;\mathbb{R} ^3)$ there exist unique $v\in H_0^1(\Omega )$ and $q\in H (\operatorname {div},\,0;\Omega )$ such that $p=\mathrm {D} v + q$.

It is worth mentioning that in the case of the $L^2$-theory, theorem 2.1 holds for any bounded domain $\Omega \subset \mathbb{R} ^3$ without having a Lipschitz boundary, see e.g. [Reference Farwig, Kozono and Sohr7]. An immediate consequence of the Helmholtz decomposition theorem is

Proof. Notice that it is sufficient to prove that

\[ \mathrm{D} H_0^1(\Omega)\subset H_0(\operatorname{curl},0;\Omega)\,. \]

For this, let us assume that $v\in H_0^1(\Omega )$ and let $\{v_n\}\subset C_0^\infty (\Omega )$ such that $v_n\rightarrow v$ in $H^1(\Omega )$. Then, for all $\phi \in C^\infty _0(\Omega )$ we obtain

\[ \int_\Omega\langle \mathrm{D} v, \operatorname{curl}\phi\rangle\,{\mathrm d} x\leftarrow\int_\Omega\langle \mathrm{D} v_n, \operatorname{curl}\phi\rangle\,{\mathrm d} x={-}\int_\Omega\langle v_n, \operatorname{div}\operatorname{curl}\phi\rangle\,{\mathrm d} x=0 \]

and $\mathrm {D} v\in H(\operatorname {curl},\,0;\Omega )$. Moreover, $\{\mathrm {D} v_n\}\subset C_0^\infty (\Omega )\cap H_0(\operatorname {curl},\,0;\Omega )$ and $\mathrm {D} v_n\rightarrow \mathrm {D} v$ in $H(\operatorname {curl};\Omega )$. As $H_0(\operatorname {curl},\,0;\Omega )$ is a closed subspace of $H(\operatorname {curl};\Omega )$ we conclude that $\mathrm {D} v\in H_0(\operatorname {curl},\,0;\Omega )$.

In an analogous way to proposition 2.2, we can prove the following lemma, from which additional regularities will be derived for the solution of system (1.2) (see corollary 4.2).

Lemma 2.3 For any bounded domain $\Omega \subset \mathbb{R} ^3$ it holds

\[ \overline{\operatorname{curl} H_0(\operatorname{curl};\Omega)}\subset H_0(\operatorname{div},0;\Omega). \]

Proof. Let us assume that $\{E_n\}\subset C_0^\infty (\Omega )$ such that $E_n\rightarrow E$ in $H(\operatorname {curl};\Omega )$. Then, for all $\phi \in C^\infty _0(\Omega )$ we obtain

\[ \int_\Omega\langle \operatorname{curl} E, \mathrm{D}\phi\rangle\,{\mathrm d} x\leftarrow\int_\Omega\langle \operatorname{curl} E_n, \mathrm{D}\phi\rangle\,{\mathrm d} x={-}\int_\Omega\langle\operatorname{div}\operatorname{curl} E_n,\phi\rangle\,{\mathrm d} x=0 \]

and $\operatorname {curl} E\in H(\operatorname {div},\,0;\Omega )$. Moreover, $\{\operatorname {curl} E_n\}\subset C_0^\infty (\Omega )\cap H_0(\operatorname {div},\,0;\Omega )$ and $\operatorname {curl} E _n\rightarrow \operatorname {curl} E$ in $H(\operatorname {div};\Omega )$. As $H_0(\operatorname {div},\,0;\Omega )$ is a closed subspace of $H(\operatorname {div};\Omega )$ we conclude that $\operatorname {curl} E\in H_0(\operatorname {div},\,0;\Omega )$.

The next embedding theorem is for instance proved in [Reference Girault and Raviart11, Sections 3.4, 3.5] and [Reference Kuhn and Pauly16] (see [Reference Grisvard14] for properties of convex sets):

Theorem 2.4 Embedding theorem

Let $\Omega \subset \mathbb{R} ^3$ be a convex domain or a domain with a $C^{1,1}$-smooth boundary $\partial \Omega$. Then

\[ H(\operatorname{curl};\Omega)\cap H_0(\operatorname{div};\Omega)\subset H^1(\Omega),\qquad\qquad H_0(\operatorname{curl};\Omega)\cap H(\operatorname{div};\Omega)\subset H^1(\Omega) \]

and there exists a constant $C>0$ such that for every $p\in H(\operatorname {curl};\Omega )\cap H_0(\operatorname {div};\Omega )$ or $p\in H_0(\operatorname {curl};\Omega )\cap H(\operatorname {div};\Omega )$ we have

\[ \|p\|_{H^1(\Omega)}\leq C(\|p\|_{H(\operatorname{curl};\Omega)} + \|p\|_{H(\operatorname{div};\Omega)})\,. \]

A version of this result for Lipschitz domains showing $H^{{1}/{2}}(\Omega )$- regularity is given in [Reference Costabel5] (similar results for bounded strong Lipschitz domains with strong Lipschitz boundary interface parts may be found in [Reference Pauly and Schomburg31, Reference Pauly and Schomburg32]). In addition, it can be noted that convex domains are strongly Lipschitz, cf. [Reference Grisvard14]. A proof for convex domains including a family of relevant boundary conditions can be found in [Reference Pauly30]. For the previous embedding theorem there are also some versions with weights, and we cite here Theorem 2.2 from [Reference Weber42] with $k=1$ and $\ell =0$. We assume that the weight function $\varepsilon :\overline \Omega \to \mathbb{R} ^{3\times 3}$ for every $x\in \overline \Omega$ is symmetric and positive definite, uniformly in $x$.

Theorem 2.5 Let $\Omega \subset \mathbb{R} ^3$ be a bounded domain with a $C^2$-smooth boundary and let $\varepsilon \in C^1(\overline \Omega,\,\mathbb{R} ^{3\times 3})$ be a symmetric and positive definite weight function. Assume that $p:\Omega \to \mathbb{R} ^3$ belongs to one of the following spaces:

(2.5)\begin{equation} p\in H_0(\operatorname{curl};\Omega)\quad\text{and}\quad \varepsilon\, p\in H(\operatorname{div};\Omega) \end{equation}

or

(2.6)\begin{equation} p\in H(\operatorname{curl};\Omega)\quad\text{and}\quad \varepsilon\, p\in H_0(\operatorname{div};\Omega)\,. \end{equation}

Then $p\in H^1(\Omega )$ and there exists a constant $C>0$ (independent of $p$) such that

\[ \|p\|_{H^1(\Omega)}\leq C\Big(\|p\|_{H(\operatorname{curl};(\Omega)} + \|\operatorname{div} (\varepsilon p)\|_{L^2(\Omega)}\Big)\,. \]

In the proof of theorem 4.1 we will decompose the microdistortion tensor $P$ as $P=\mathrm {D} q + Q$ and apply theorem 2.4 to $Q$. The regularity for the displacement field $u$ and the vector $q$ then is a consequence of an elliptic regularity result that we discuss next.

Let us consider the following auxiliary bilinear form: for $(u,\,q)\in H^1_0(\Omega ;\mathbb{R} ^{3+3})$ and $(u,\,v)\in H^1_0(\Omega ;\mathbb{R} ^{3+3})$ we define

(2.7)\begin{equation} \tilde{a}\left(\!\begin{pmatrix} u\\ q \end{pmatrix},\begin{pmatrix} v\\ w \end{pmatrix}\!\right) = \int_\Omega \langle \mathbb{A}(x)\begin{pmatrix} \operatorname{sym}\mathrm{D} u\\ \operatorname{sym}\mathrm{D} q \end{pmatrix},\quad \begin{pmatrix} \operatorname{sym}\mathrm{D} v\\ \operatorname{sym}\mathrm{D} w \end{pmatrix}\rangle\, {\mathrm d} x, \end{equation}

where $\mathbb{A} :\Omega \rightarrow (\operatorname{Lin} (\operatorname {Sym}(3),\,\operatorname {Sym}(3)))^4$ is defined by the following formula

(2.8)\begin{equation} \mathbb{A}(x)=\begin{pmatrix} {\mathbb{C}_{{\rm e}}}(x) & -{\mathbb{C}_{{\rm e}}}(x)\ - {\mathbb{C}_{{\rm e}}}(x) & {\mathbb{C}_{{\rm e}}}(x) + {\mathbb{C}_{{\rm micro}}}(x) \end{pmatrix}. \end{equation}

Corollary 2.7 Let Assumption $\bf {A}_{(ii)}$ be satisfied. Then, there exists a positive constant $C_{\mathbb{A} }$ such that for all $x\in \overline \Omega$ and $\sigma =(\sigma _1,\,\sigma _2)\in \operatorname {Sym}(3)\times \operatorname {Sym}(3)$ we have:

(2.9)\begin{equation} \langle\mathbb{A}(x)\sigma,\sigma\rangle\geq C_{\mathbb{A}}|\sigma|^2\,. \end{equation}

Proof. Fix $x\in \overline \Omega$ and $\sigma =(\sigma _1,\,\sigma _2)\in \operatorname {Sym}(3)\times \operatorname {Sym}(3)$, then

\[ \langle\mathbb{A}(x)\sigma,\sigma\rangle= \langle{\mathbb{C}_{{\rm e}}}(\sigma_1-\sigma_2),\sigma_1-\sigma_2\rangle+\langle{\mathbb{C}_{{\rm micro}}}(\sigma_2),\sigma_2\rangle\,.\nonumber \]

Assumption $\bf {A}_{(ii)}$ implies

\[ \begin{aligned} \langle\mathbb{A}(x)\sigma,\sigma\rangle & \geq C_{\mathrm{e}}|\sigma_1-\sigma_2|^2 +C_{\mathrm{micro}}|\sigma_2|^2\geq \min\{C_{\mathrm{e}},C_{\mathrm{micro}}\}\big(|\sigma_1-\sigma_2|^2+|\sigma_2|^2\big)\nonumber\\ & \geq \frac{2}{9}\min\{C_{\mathrm{e}},C_{\mathrm{micro}}\}\big(|\sigma_1|^2+|\sigma_2|^2\big)=\frac{2}{9}\min\{C_{\mathrm{e}},C_{\mathrm{micro}}\}|\sigma|^2 \end{aligned} \]

and the proof is completed.

Now, for all $(u,\,q)\in H^1_0(\Omega ;\mathbb{R} ^{3+3})$ we have

(2.10)\begin{align} \tilde{a}\left(\!\begin{pmatrix} u\\ q \end{pmatrix},\begin{pmatrix} u\\ q \end{pmatrix}\!\right)& \geq C_{\mathbb{A}}\big(\|\operatorname{sym}\mathrm{D} u\|^2_{L^2(\Omega)}+\|\operatorname{sym}\mathrm{D} q\|^2_{L^2(\Omega)}\big)\nonumber\\ & \geq C_{\mathbb{A}}\,C_{K}\big(\|u\|^2_{H^1_0(\Omega)}+\|q\|^2_{H^1_0(\Omega)}\big)\,, \end{align}

where the constant $C_{K}$ is a constant resulting from the standard Korn's inequality [Reference Neff22]. This shows that the bilinear form (2.7) is coercive on the space $H^1_0(\Omega ;\mathbb{R} ^{3+3})$. The form (2.7) defines the following auxiliary problem: for $(F_1,\,F_2)\in L^2(\Omega ;\mathbb{R} ^{3+3})$ find $(u,\,q)\in H^1_0(\Omega ;\mathbb{R} ^{3+3})$ with

(2.11)\begin{equation} \tilde{a}\big(\left(\begin{smallmatrix} u\\ q \end{smallmatrix}\right),\left(\begin{smallmatrix} v\\ w \end{smallmatrix}\right)\big)= \int_\Omega \left\langle \left(\begin{smallmatrix} F_1\\ F_2 \end{smallmatrix}\right),\left(\begin{smallmatrix} v\\ w \end{smallmatrix}\right) \right\rangle\, {\mathrm d} x \end{equation}

for all $(v,\,w)\in H^1_0(\Omega ;\mathbb{R} ^{3+3})$. Modifying the results concerning the regularity of elliptic partial differential equations, it would be possible to obtain the existence of a solution for system (2.11) with the regularity $(u,\,q)\in H^1_0(\Omega ;\mathbb{R} ^{3+3})\cap H^2(\Omega ;\mathbb{R} ^{3+3})$ (see for example [Reference Gilbarg and Trudinger10, Theorem 9.15, Section 9.6]). However, system (2.11) fits perfectly into the class considered in [Reference Neff and Knees26]. There, the global regularity of weak solutions to a quasilinear elliptic system with a rank-one-monotone nonlinearity was investigated. As an application of the result from [Reference Neff and Knees26] we obtain

Proof. Coercivity (2.10) of the bilinear form (3.1) and the Lax-Milgram theorem imply the existence of exactly one weak solution $(u,\,q)\in H^1_0(\Omega ;\mathbb{R} ^{3+3})$. In order to prove higher regularity of this solution we will use Theorem $5.2$ of [Reference Neff and Knees26].

Let us introduce $\mathbb {B}:\overline \Omega \times \mathbb{R} ^{(3+3)\times 3}\rightarrow \mathbb{R} ^{(3+3)\times 3}$ as the unique $x$-dependent linear mapping satisfying

(2.12)\begin{equation} \left\langle \mathbb{B}\Big(x, \left(\begin{smallmatrix} A_1\\ A_2 \end{smallmatrix}\right) \Big), \left(\begin{smallmatrix} B_1\\ B_2 \end{smallmatrix}\right)\rangle =\langle \mathbb{A}(x) \left(\begin{smallmatrix} \operatorname{sym} A_1\\ \operatorname{sym} A_2 \end{smallmatrix}\right),\quad \left(\begin{smallmatrix} \operatorname{sym} B_1\\ \operatorname{sym} B_2 \end{smallmatrix}\right) \right\rangle \end{equation}

for all $A_1,\,A_2,\,B_1,\,B_2\in \mathbb{R} ^{3\times 3}$ and $x\in \overline \Omega$. Then for every $x\in \overline {\Omega }$, $A=(A_1,\,A_2)\in \mathbb{R} ^{(3+3)\times 3}$, $\xi =(\xi _1,\,\xi _2)\in \mathbb{R} ^{3+3}$ and $\eta \in \mathbb{R} ^3$ we have thanks to the positive definiteness of $\mathbb{A}$

(2.13)\begin{equation} \begin{aligned} & \big\langle\,\mathbb{B}\Big(x,\left(\begin{smallmatrix} A_1\\ A_2 \end{smallmatrix}\right) +\xi\otimes\eta\Big)\\& \qquad-\mathbb{B}\Big(x, \left(\begin{smallmatrix} A_1\\ A_2 \end{smallmatrix} \right) \Big),\xi\otimes\eta\,\big\rangle\\ & \quad\geq C_{\mathbb{A}} \big(\|\operatorname{sym}(\xi_1\otimes \eta)\|^2 + \|\operatorname{sym}(\xi_2\otimes \eta)\|^2\big)\,. \end{aligned} \end{equation}

Since $\|\operatorname {sym}(\xi _i\otimes \eta )\|^2=1/2(\|\xi _i\|^2\|\eta\|^2 + \|\langle \xi _i,\,\eta \rangle\|^2)$, this ultimately implies that $\mathbb {B}$ is strongly rank-one monotone/satisfies the Legendre-Hadamard condition. Due to the Lipschitz continuity of ${\mathbb {C}_{{\rm e}}}$ and ${\mathbb {C}_{{\rm micro}}}$ the remaining assumptions of Theorem $5.2$ of [Reference Neff and Knees26] can easily be verified. Hence, [Reference Neff and Knees26, Theorem 5.2] implies $(u,\,q)\in H^2(\Omega ;\mathbb{R} ^{3+3})$.