Abstract
We prove that microstructures in shape-memory alloys have a self-similar refinement pattern close to austenite-martensite interfaces, working within the scalar Kohn-Müller model. The latter is based on nonlinear elasticity and includes a singular perturbation representing the energy of the interfaces between martensitic variants. Our results include the case of low-hysteresis materials in which one variant has a small volume fraction. Precisely, we prove asymptotic self-similarity in the sense of strong convergence of blow-ups around points at the austenite-martensite interface. Key ingredients in the proof are pointwise estimates and local energy bounds. This generalizes previous results by one of us to various boundary conditions, arbitrary rectangular domains, and arbitrary volume fractions of the martensitic variants, including the regime in which the energy scales as \(\varepsilon ^{2/3}\) as well as the one where the energy scales as \(\varepsilon ^{1/2}\).
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1 Introduction
Fractal microstructures, characterized by self-similar refinement of oscillations close to a Dirichlet boundary, have been studied in models of a variety of physical problems, including micromagnetism, shape-memory alloys, and compressed thin elastic sheets. They were first introduced by Landau in the 30s in the context of magnetism [44, 45], and meanwhile a rich mathematical literature has been developed. In most cases the main result is a rigorous characterization of the scaling of the energy in terms of the various parameters of the system, up to a universal multiplicative constant. The upper bound is typically obtained by an explicit construction which is based on self-similar microstructures. This is complemented by a matching lower bound, which proves that this microstructure achieves the optimal energy up to a universal factor, and thereby supports the idea that the actual minimizers are indeed, at least approximately, self-similar. Only in very few cases it has been possible to prove detailed properties of the minimizers themselves, including in particular the fact that they exhibit, up to boundary effects, the expected self-similar structure.
Mathematical work on the subject was initiated by Kohn and Müller in the 90s [40, 41]. They proposed a scalar, two-dimensional model for microstructure in shape-memory alloys close to an austenite-martensite interface. In their model one partial derivative is constrained to take only two values, leading to the characteristic non-convexity. Their work has been meanwhile generalized to different volume fractions [19, 59], to vectorial settings in the context of linearized elasticity [3, 10, 11, 23, 36, 38, 39, 49, 52] and to geometrically nonlinear formulations [12, 50]. These vectorial generalizations have confirmed that the Kohn-Müller scalar model indeed captures the correct scaling of the energy. A number of other problems have then been addressed with similar tools, including magnetization patterns in uniaxial ferromagnets [14, 15, 37], diblock copolymers [1, 13], flux tubes in type-I superconductors [16, 20, 22, 28], wrinkling in thin elastic films [4, 6, 7, 34], dislocation microstructures [18, 19], transport network structures [8, 9], and compliance minimization [42].
We consider here a version of the Kohn-Müller model which is appropriate for modeling materials where the austenite is almost compatible with one martensitic variant, which are known to have particularly low hysteresis [24, 58]. Specifically, we work in a rectangle \(R^{L_{x},L_{y}}:=(0,L_{x})\times (0,L_{y})\) and minimize the functional
over the set \(\mathcal{A}_{0}\) of admissible \(u\), defined by
Here and below, \(u_{x}\), \(u_{y}\) and \(u_{yy}\) denote distributional partial derivatives of the function \(u\), and \(|u_{yy}|(\omega )\) denotes the total variation of the measure \(u_{yy}\) on the set \(\omega \). The interface with austenite is modeled by the boundary condition \(u(0,\cdot )=0\). The parameter \(\varepsilon \) represents the surface energy per unit length, and \(\theta \in (0,1)\) represents the volume fraction of the minority phase, by symmetry it suffices to consider the case \(\theta \le \frac{1}{2}\). The interpretation of the parameter \(\theta \) in terms of the crystallography of the phase transition, the relation of the limit \(\theta \to 0\) to the so-called “\(\lambda _{2}=1\)”-condition, and its importance for the development of low-hysteresis materials have been discussed in [2, 24, 29, 33, 46, 53, 56–59], see the recent survey [32] for an overview. In the case of equal volume fractions, \(\theta =\frac{1}{2}\), the present model reduces to the one originally studied by Kohn and Müller. A variant of \(I\) in which the Dirichlet boundary condition is replaced by the elastic energy of austenite outside \(R^{L_{x}, L_{y}}\) has been studied in [19], a vectorial extension in [23], resulting in a rich phase diagram. The limit \(\varepsilon \sim \theta ^{2}\to 0\) of a similar model was addressed in [21].
1.1 Main Results
In this paper, we study the functional in (1), characterize the energy scaling (Theorem 1), prove asymptotic self-similarity of minimizers (Theorem 2), and obtain quantitative pointwise bounds on the minimizer (Theorem 3). In particular, we generalize the results from [17] in several ways (see below). We build on the theses [25, 43] by two of the authors, in which some of the results from [17, 41] have been extended to arbitrary volume fractions.
Related results for a three-dimensional analogue of the Kohn-Müller model, which arises in the study of uniaxial ferromagnets, have been obtained in [55]. Local bounds for the energy and the minimizers have been obtained for a related nonlocal isoperimetric problem, motivated by the study of diblock copolymers, in [1] and recently for surface charges in [5], and for the three-well problem in [51, Lemma 4].
We focus here on the minimization of \(I\) over the set \(\mathcal{A}_{0}\) (see (2)) but we point out that all our results can be extended to the case of periodic boundary conditions, see Sect. 8. Existence of miminizers was proven for \(\theta =\frac{1}{2}\) in [41, Th. 2.1], the argument works for any value of \(\theta \) without changes.
We first characterize the scaling of the optimal energy.
Theorem 1
Global scaling laws
There is \(c>0\) such that for all \(\varepsilon , L_{x}, L_{y}>0\) and \(\theta \in (0,\frac{1}{2}]\) one has
This result extends [41] and is a special case of [19]. For convenience of the reader, the short proof in this context is given in Sect. 4, with the upper bounds being an easy byproduct of the constructions we present in Sect. 3. In both scaling regimes, the upper bound can be achieved by constructions that refine in a self-similar way close to the interface, see Fig. 1.
This observation has been refined in [17] where asymptotic self-similarity of minimizers for (1) is proven under rather strong Dirichlet boundary conditions in the case of \(\theta =\frac{1}{2}\) and very short rectangles, deep into the second scaling regime \(\varepsilon ^{2/3}\theta ^{2/3}L_{x}^{1/3}L_{y}\) from Theorem 1. In Theorem 2 below we generalize this result to the physically important case of Neumann (and periodic, see below) boundary conditions, allowing for arbitrary volume fractions \(\theta \) (including the low-hysteresis case \(\theta \ll 1/2\)), and to more general domains, including long thin rectangles (corresponding to the first energy scaling regime from Theorem 1). Our results in particular show that the Dirichlet boundary conditions and the shape of the domain chosen in [17] do not modify significantly the behavior of the minimizers. Indeed, one important tool in our proof is a method to obtain effective boundary conditions on subsets of the domain from the assumption that the scaling of the energy is the optimal one, and then to iteratively improve these bounds passing to smaller and smaller subsets of the domain, as explained in more detail in Sect. 2. Precisely, in Sect. 7, we prove the following result.
Theorem 2
Asymptotic self-similarity of a minimizer
Let \(\varepsilon , L_{x}, L_{y}>0\) and \(\theta \in (0,\frac{1}{2}]\). Let \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) be a minimizer of \(I(u,R^{L_{x},L_{y}})\). For any \(y_{0} \in (0, L_{y})\) and any sequence \(\nu _{j}\to 0\), \(\nu _{j}>0\) we define
(implicitly extending \(u\) by zero to the rest of \(\mathbb{R}^{2}\)). Then the sequence \(u^{j}\) has a subsequence that converges strongly in \(W^{1,2}_{\mathrm{loc}}((0,\infty )\times \mathbb{R})\) towards a function \(u^{\infty }\in \mathcal{A}_{0}((0,\infty )\times \mathbb{R})\), and \(u^{\infty }\) is a local minimizer.
For the precise definition of a local minimizer we refer to the notation below. The main step in the proof of asymptotic self-similarity is the proof of local bounds. Roughly speaking, on suitable subrectangles we show pointwise bounds of the form
and local energy bounds of the form
Optimality of these exponents follows from Remark 2 and Theorem 1, respectively. Since we do not impose boundary conditions on the top and bottom boundaries, the estimates degenerate close to the boundaries. This is made quantitative in Theorem 3 by the dependence of the constants on \(\eta \). The option of making the aspect ratio of the considered regions larger, by enlarging \(c_{1}\), will be important in the proof of Theorem 2. We remark that in [17, Theorem 2.1] (see [43] for the case of arbitrary \(\theta \in (0,1/2]\)), corresponding results are proven under rather restricted Dirichlet boundary conditions on the top and bottom of the rectangle, analogously to what was discussed above for asymptotic self-similarity. In this case, one can set \(\eta =1\) in (6) and \(\eta =0\) everywhere else.
Precisely, we prove the following result, see Sect. 6.
Theorem 3
Local bounds
Let \(\eta \in (0,\frac{1}{6})\), \(k_{1}>0\). Then there are constants \(c_{1}^{*}, c_{2}> 0\) such that for all \(c_{1} \ge c_{1}^{*}\) there exist constants \(d_{1}, d_{2} > 0\) with the following property. Let \(\varepsilon , L_{x}, L_{y}>0\) and \(\theta \in (0,\frac{1}{2}]\), and let \(l_{x}\in (0,L_{x}]\) such that
and let \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) be a local minimizer of \(I(\cdot , R^{L_{x}, L_{y}})\) such that
and
Then
and, for all \(l\in (0,l_{x}]\) and \((a,b)\subseteq (3\eta L_{y}, (1-3\eta )L_{y})\) with \(b-a \ge 4c_{1} \varepsilon ^{1/3}\theta ^{-2/3}l^{2/3}\),
We note that here we capture also the expected scaling in the volume fraction \(\theta \). This introduces additional technical difficulties compared to [17, 41]. In particular, in the construction of Sect. 3, the choice of the position of the interfaces needs to more accurately reproduce the local volume fraction induced from the boundary conditions. In the proof of the local bounds in Sect. 6 the relation between \(L^{2}\) and \(L^{\infty }\) bounds changes, and requires a different treatment of the regions close to the top and bottom boundaries. While the explicit behaviour on \(\theta \) is not necessary to obtain asymptotic self-similarity of minimizers (see Theorem 2), we expect that such bounds might be helpful for proving explicit self-similarity of minimizers in the limit of low volume fractions, which could be taken along the lines of [21]. For a slightly simpler model arising in the variational study of type-I-semiconductors, the explicit self-similar minimizer is completely charcterized in the limit of low-volume fractions in [28]. To the best of our knowledge, this is the only case in which self-similarity of a minimizer is known.
1.2 Outline of the Article
The rest of the article is structured as follows. After briefly introducing the notation, we give a summary of the mathematical strategy in Sect. 2 and then provide an explicit branching-type construction of a test function for given Dirichlet boundary data in Sect. 3 (see Proposition 1). In Sect. 4, we recall the global scaling law (see Theorem 1) for the minimal energy. Subsequently, in Sect. 5, we show that the energy of a minimizer restricted to subrectangles of the form \((0,l_{x})\times (0,L_{y})\) for \(l_{x}\leq L_{x}\) has the same scaling behaviour as the minimal energy on the smaller rectangle (see Theorem 4). In Sect. 6, we prove the analogous energy scaling result on suitable subrectangles of the form \((0,l_{x})\times (a,b)\subseteq R^{L_{x},L_{y}}\) complemented with an \(L^{\infty }\)-bound on minimizers (see Theorem 3). Section 7 is devoted to the proof of asymptotic self-similarity of minimizers (see Theorem 2). Finally, in Sect. 8, the results are generalized to periodic boundary conditions on top and bottom.
1.3 Notation
For a rectangle \(R\) we denote by \(\mathcal{A}(R)\) the set of admissible functions on \(R\),
so that the set \(\mathcal{A}_{0}\) defined in (2) is given by those \(u\in \mathcal{A}\) such that \(u(0,y)=0\) for all \(y\). Elements of \(\mathcal{A}(R)\) have a Hölder-continuous representative (see Lemma 7) and in particular have a trace on \(\partial R\). The set \(\mathcal{A}((0,\infty )\times \mathbb{R})\) is defined as the set of those \(u:(0,\infty )\times \mathbb{R}\to \mathbb{R}\) which belong to \(\mathcal{A}((0,L)\times (-H,H))\) for all \(L,H>0\), and analogously for \(\mathcal{A}_{0}\).
A function \(u \in \mathcal{A}_{0}((0,l)\times (a,b))\) is called local minimizer if the energy cannot be decreased by compact perturbations, in the sense that
A function \(u\in \mathcal{A}_{0}((0,\infty )\times \mathbb{R})\) is a local minimizer if all restrictions of \(u\) to rectangles \((0,l)\times (a,b)\) are local minimizers. Moreover, a function \(u \in \mathcal{A}(R^{l_{x}, l_{y}})\) is called minimizer with respect to its own boundary conditions if
We stress that in this definition it is not required that the values of \(u_{y}\) and \(v_{y}\) on the boundary coincide.
If \(u\) is a local minimizer or a minimizer with respect to its own boundary data on \(R^{l_{x},l_{y}}\), and \(R'=(0, l_{x}-\delta )\times (\delta , l_{y}-\delta )\) for some \(\delta \in (0,\min \{\frac{1}{2} l_{y}, l_{x}\})\), then \(u\) is automatically a local minimizer on \(R'\). However, it is not clear that \(u\) is a minimizer with respect to its own boundary data in \(R'\). Indeed, in the second case for the construction of a competitor one may insert jumps in the normal derivative on the two horizontal boundaries.
For \(f:[0,l_{x}]\to \mathbb{R}\), we denote the linear interpolation by
2 Outline of the Main Arguments
In this section we provide a brief summary of the general strategy and of the main mathematical ideas leading to the proof of asymptotic self-similarity. Many ideas and results are extensions of those developed in [17, 25, 41, 43]. For the sake of simplicity, we suppress the constants in the following estimates, using \(f\lesssim g\) to mean that there is \(c>0\) such that \(f\le c g\) for all values of the parameters, and \(f\sim g\) to mean \(f\lesssim g\) and \(g\lesssim f\). We remark however that one important technical difficulty in the proofs is finding suitable values of the constants which permit to carry out the inductive argument sketched below (Step 3 in the proof of Theorem 3), therefore in the proofs we name the important constants explicitly. In this discussion we focus on a minimizer \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) of \(I(\cdot , R^{L_{x}, L_{y}})\), some results are more general.
The starting point is a method to bound the energy of \(u\) on a subset of its domain, say \(R':=(0, l_{0})\times (a, b)\), obtained by constructing a competitor \(v\) which coincides with \(u\) outside \(R'\). Proposition 1 below presents the explicit construction of a test function which matches given boundary data on the four sides of \(R'\). The boundary data are called \(u^{T}\) (top side), \(u^{B}\) (bottom side), \(u^{L}=0\) (left side), \(u^{R}\) (right side).
The first part of the construction (Steps 1-4) considers only the vertical boundaries. By convexity it is immediate to see that \(v(0,\cdot )=0\) and \(v(l_{0},\cdot )=u^{R}\) imply
where \(v^{l}\) is the linear interpolation of \(v\) on \(R'\), i.e. \(v^{l}(x,y) \coloneqq \frac{x}{l_{0}} v(l_{0}, y) =\frac{x}{l_{0}} u^{R}(y)\) (see (12)). Obviously, the boundary data yield \(v^{l}=u^{l}\). Further, due to the quadratic nature of the energy, one can separate this “linear” contribution (in the sense of being the elastic energy of the linear interpolation between the boundary values), which only depends on the boundary data, from the “excess” energy, which arises from the oscillations around the linear interpolation,
As the third term is fixed, we focus on the first two. The test function in Proposition 1 exhibits self-similar branching near the left and right boundaries (as illustrated in Fig. 1 for the left boundary), and its excess energy has the optimal scaling \(\varepsilon ^{2/3}\theta ^{2/3}l_{0}^{2/3}(b-a)\). The branching construction includes a careful choice of the vertical subdivision of the domain, which is important if \(\theta \) is small. This requires that the domain is (in the vertical direction) larger than the natural length scale of the microstructure, which is of order \(\varepsilon ^{1/3}\theta ^{-2/3}l_{0}^{2/3}\). This is the natural lower bound on the height of the subsets we can consider, there is no lower bound on the width \(l_{0}\).
In the final step (Step 5), we modify the construction in order to fulfill also the boundary conditions on the top and bottom sides. Due to the hard constraint \(v_{y}\in \{1-\theta ,-\theta \}\) we cannot use a smooth cutoff function. We instead take locally the maximum or the minimum between the function \(v\) obtained with branching and new functions which obey the boundary data on the horizontal boundaries (but not on the vertical ones); for example, \(w(x,y):=u^{B}(x)+(1-\theta )(y-a)\) is the largest function which obeys \(w_{y}\in \{1-\theta ,-\theta \}\) and \(w(\cdot , a)=u^{B}\). The function \(\tilde{v}:=\min \{v,w\}\) obeys \(\tilde{v}_{y}\in \{1-\theta ,-\theta \}\) everywhere, \(\tilde{v}(\cdot ,a) \le u^{B}\) and creates at most one additional interface. Since \(\tilde{v}_{x}\in \{v_{x}, w_{x}\}=\{v_{x}, u^{B}_{x}\}\), the additional cost of elastic energetic can be controlled by
where \({\omega ^{B}/\theta }\) is a bound on the thickness of the interpolation layer, which in turn can be estimated in terms of \(u^{B}-v\). As the branching construction gives a good bound on \(|v-v^{l}|\), \(\omega ^{B}\) can be estimated via the distance between \(u^{B}(x)\) and \(v^{l}(x, y)=\frac{x}{l_{0}}u(l_{0},y)\). Therefore the procedure requires control of (14) and uniform control of \(u(l_{0},\cdot )\). An analogous construction is carried out on the other side, and Proposition 1 follows.
The rest of the paper builds on this local bound to prove specific properties of minimizers, using several bootstrapping arguments in order to obtain appropriate control of the local boundary conditions. As explained above, Proposition 1 can be used to obtain the local energy bound (5), of the form
only if we have a good bound on the quantity in (14) and on \(\omega ^{B}\) (and the same on the top side), which in turn requires a local uniform bound of the type
The latter is essentially equivalent to (4), which for this reason is closely linked to (5).
We shall discuss below how Proposition 1 permits to prove (15) from (16), and how the constraint can be used to prove (16) from (15). The apparent circularity of this argument can be circumvented, using the fact that (15) deteriorates only moderately if \(l\) is decreased by a fixed factor. Therefore one can prove the two estimates jointly by an inductive procedure, where at step \(i\) one considers \(l\sim x\sim \phi ^{i} L_{x}\), for some \(\phi \in (0,1)\) chosen below. It is crucial to make sure that the constants implicit in the two bounds do not deteriorate in the inductive step. This is technically subtle but possible, since both estimates contain a “main” contribution from the construction, which has a universal constant, and smaller error terms from the “previous round”, whose constant deteriorates but which do not constitute the leading-order contribution, at least if the shape of the rectangles is chosen appropriately. We refer to the proof of Theorem 3 for details.
In the following we briefly outline the mathematical arguments to obtain the bounds of (15) and (16). In order to get started, we assume the two bounds to hold for some \(l=l_{0}\) and some (well-chosen) \(a_{0},b_{0}\), with \([a_{0},b_{0}]\) covering most of \([0, L_{y}]\) (for any minimizer we can find values where this holds, see Step 1 in the proof of Theorem 3). We then consider the function
We know that \(f(a_{0},b_{0})\lesssim \varepsilon ^{2/3}\theta ^{2/3} l^{1/3}(b_{0}-a_{0})\). Let us for a moment fix \(b=b_{0}\) and focus on the nonincreasing function \(f(\cdot , b_{0})\). If it has a large derivative, then \(f\) becomes rapidly smaller with increasing \(a\), and the desired bound follows. If instead the derivative is small, then we obtain a good bound on the quantity in (14) and, given that we globally control \(\omega ^{B}\), Proposition 1 and the comparison discussed above (considering the box \((0,l)\times (a,b_{0})\)) lead us to the desired upper bound for \(f(a,b_{0})\). Of course, we need to make sure that the “top” boundary condition does not cause problems, this is the key criterion in choosing \(b_{0}\). Combining the two cases, and repeating the procedure with \(b\), one obtains
which is (15) for \(l = l_{0}\). This leads easily to an \(L^{2}\) bound on \((u-u^{l})(x, \cdot )\) over any admissible segment \((a,b)\), for any \(x\in (0,l_{0})\),
Combining this with the definition of \(u^{l}\) one obtains an \(L^{2}\) bound on \(u(x,\cdot )\). This can be directly turned into an \(L^{\infty }\) bound using the fact that \(u(x,\cdot )\) is 1-Lipschitz, see (48) below. However, the resulting estimate does not have the optimal scaling in \(\theta \). Indeed, \(u_{y}\in \{1-\theta ,-\theta \}\) gives a stronger condition on the negative part of the derivative. This is exploited in Lemma 4 to obtain
for \(y \in (a+\delta ,b-\delta )\) and \(\delta \in (0,\frac{b-a}{2})\), we shall choose \(b-a \sim \varepsilon ^{1/3}\theta ^{-2/3}l_{0}^{2/3} \) and \(\delta \coloneqq (x/l_{0})^{1/3}(b-a)\). The first term can be controlled from (16), the second one from (15). The fact that the first term is linear in \(x\), whereas the desired estimate scales as \(x^{2/3}\), permits to escape the iterative deterioration of the constant. This leads to a proof of (16) for \(l_{1}:=\phi l_{0}\). In order to continue on \((0, l_{1})\) one observes that (15) for \(l=l_{0}\) implies (15) for \(l=l_{1}:=\phi l_{0}\) with a constant which is \(\phi ^{-1/3}\) times larger, and continues inductively.
The local bounds in (16) and (15) are one ingredient in the proof of the asymptotic self-similarity of a minimizer \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) in the sense of blow-ups with respect to local strong convergence in \(W^{1,2}\). The main difficulty in proving the strong convergence of the sequence \((u^{j})_{j}\) (introduced in (3)) is the proof of the strong convergence of the \(x\)-derivatives in \(L^{2}_{\mathrm{loc}}\). The Hölder-continuity of \(u\) (see Lemma 7) and the local energy scaling law presented in Lemma 4 allow us to choose a subrectangle \((0, l) \times (0,L_{y}) \subseteq R^{L_{x}, L_{y}}\) on which the assumption of Theorem 3 are satisfied. Due to Theorem 3 we know that (15) and (16) hold on \(R\coloneqq (0, l_{x}) \times (3\eta L_{y}, (1-3\eta )L_{y})\) for some fixed \(\eta \in (0, \frac{1}{6})\). Thus, we have the uniform bounds
and by a change of variables,
for \(\varepsilon ^{1/3} \theta ^{-2/3} l^{2/3} \lesssim b-a\). Taking a diagonal sequence, we obtain the existence of a function \(u^{\infty }\in W^{1,2}_{\mathrm{loc}}((0,\infty )\times \mathbb{R})\) obeying
-
(i)
\(u^{j} \rightharpoonup u^{\infty }\) weakly in \(W^{1,2}_{\mathrm{loc}}((0, \infty ) \times \mathbb{R})\),
-
(ii)
\(u^{j}_{yy} \rightharpoonup u^{\infty }_{yy}\) weakly as Radon measures on \((0, \infty ) \times \mathbb{R}\),
-
(iii)
\(u^{j} \rightarrow u^{\infty }\) uniformly in every compact set \(K \subseteq [0, \infty ) \times \mathbb{R}\).
Using compensated compactness, (i) and (ii) imply the strong convergence of \((u_{y}^{j})_{j}\) towards \(u^{\infty }_{y}\) in \(L^{2}_{\mathrm{loc}}\). By lower-semi-continuity, (18) and (19) are also true for \(u^{\infty }\).
We continue by proving the existence of a subsequence \((u^{j})_{j}\) such that the sequence \((u^{j}_{x})_{j}\) strongly converges towards \(u^{\infty }_{x}\) in \(L^{2}(R^{l,h})\) for all \(l, h > 0\) with \(R_{l,h} \coloneqq (0, l) \times (-h, h)\). For that, we show
for \(l > 0\) and \(\varepsilon ^{1/3}\theta ^{-2/3}l^{2/3} \lesssim H\). Applying (20) two times and using (19) to estimate the \(L^{2}\)-norm of \((u^{j})_{j}\) and \(u^{\infty }\) implies \(u_{x}^{j} \rightarrow u_{x}^{\infty }\) in \(L^{2}(R^{l, h}) \) as \(j \rightarrow \infty \) for any \(l, h > 0\).
The proof of (20) contains several technical difficulties. Starting point is the identity
which motivates to introduce for an appropriately chosen fixed \(H\gtrsim \varepsilon ^{1/3}\theta ^{-2/3}l^{2/3}\) the function \(f_{j}\colon (0, H) \rightarrow \mathbb{R}\),
By weak convergence and lower semi-continuity, \(f_{j}\to 0\) pointwise, and hence, by Egorov’s theorem, uniformly on a set of large measure. It remains to bound the difference \(I(u^{j}; R_{l, h}) - I(u^{\infty }; R_{l,h})\) which is again done by constructing a competitor \(w^{j}\) to \(u^{j}\). Roughly speaking, \(w^{j}\) is constructed to agree with \(u^{\infty }\) well in the interior of the rectangle and equals to \(u^{j}\) far outside. The main difficulty (compared to the construction in Proposition 1) is that we want the difference of the energies of \(w^{j}\) and \(u^{\infty }\) to converge towards zero and not just to be uniformly bounded. For that, we consider larger rectangles, and provide a careful treatment of the interpolation layers, with different arguments at the right (vertical) boundary and the top and bottom (horizontal) boundaries, respectively, see Sect. 7 and in particular Fig. 8 there. Let us briefly explain the main ideas of these two interpolations.
For the right boundary, we consider a small interpolation layer of width \(l_{j}:={l}\|u^{j}-u^{\infty }\|_{L^{\infty }(R_{2l_{x}},H)}\) which for \(j\to \infty \) tends to zero by (iii). Here, we take the function \(u^{j}\) and truncate it at \(u^{\infty }(x,y)\pm \frac{x-{l}}{{l}}\) from above and below, respectively. Note that this indeed interpolates between \(u^{\infty }\) for \(x\leq {l}\) and \(u^{j}\) for \(x\geq {l}+l_{j}\), and yields an admissible test function \(\tilde{u}^{{j}}\). While the elastic energy of the interpolation is easily estimated by explicit computation, the surface energy requires a counting argument that is presented after (102).
The interpolation on top and bottom of the rectangle is more subtle and is worked out in Lemma 8. Let us consider only the top boundary. The interpolation takes place on (large) layers \((0,l+l_{j})\times (h_{j}-h,h_{j})\) of height \(h\), see Fig. 8. Here the \(h_{j}\) have to be chosen carefully such that in particular \(u_{y}\) does not jump on \(\{y=h_{j}\}\) and the elastic energy of \(u^{j}\) or \(u^{\infty }\), the difference of the \(x\)- and the \(y\)-derivatives of \(u^{j}\) and \(u^{\infty }\) do not concentrate on \(\{y=h_{j}\}\). The last condition in particular means that
where
Our goal is to construct an admissible function \(w^{j, T}\) on \(R^{T}_{j}\coloneqq (0, l + l_{j})\times (h_{j} - h, h_{j})\) which agrees (up to the derivative) with \(\tilde{u}^{j}\) on the top boundary, with \(u^{j}\) on the bottom boundary, and with both on the right boundary, and
The key observation is that a small change in the boundary values can be generated with a small change in energy, if one refrains from creating new interfaces but instead moves smoothly the existing ones, thereby varying the local volume fraction of the two phases on each segment \(\{x\}\times (h_{j}-h,h_{j})\), as sketched in Fig. 6 below. Indeed, this local volume fraction is in one-to-one correspondence with the difference between the value of the function on the top and bottom boundaries,
Therefore the required boundary values can be attained by changing this volume fraction by a factor \(\alpha ^{j}(x)\) depending on \(\tilde{u}^{j}(x, h_{j})\), \(\tilde{u}^{j}(x, h_{j}-h)\), and \(u^{j}(x, h_{j})\). This factor is close to one since \(\tilde{u}^{j}\) and \(u^{j}\) converge locally uniformly to the same function. We refer to Steps 1 and 2 of the proof of Lemma 8 for details. One then can verify that the energy estimate (23) is fulfilled. Putting things together, \(I(u^{j}, R_{l, h_{j}}) - I(u^{\infty }, R_{l, h_{j}}) \lesssim \varepsilon l \eta _{j}^{1/2}\). Recalling (22) one obtains (20) together with (21), (23) for the bottom and top area and \(\vert f_{j}(h_{j})\vert \rightarrow 0\) as \(j \rightarrow \infty \). This concludes the proof of strong convergence.
3 Explicit Construction
In this section, we will present the construction of a test function with given Dirichlet boundary conditions for which the energy can be controlled in terms of the boundary conditions. This will be used later to modify a given function on subrectangles of the domain. The construction is taken from [25] and is a generalization to the unequal volume-fraction case of the construction from [17, Sect. 2.1], which in turn builds upon [41, Sect. 2].
Proposition 1
Local estimate of the energy
There is \(\tilde{c}_{0}>0\) such that for all \(\varepsilon >0\), \(\theta \in (0,1/2]\), \(l_{x}>0\), and \(l_{y}\in [\varepsilon ^{1/3}\theta ^{-2/3}l_{x}^{2/3},+\infty )\) the following holds: Suppose that \({u^{T}, u^{B}} \colon [0, l_{x}] \rightarrow \mathbb{R}\) and \({u^{L}, u^{R}} \colon [0, l_{y}]\rightarrow \mathbb{R}\) are continuous, weakly differentiable with \(u^{L}_{y} \coloneqq (u^{L})' \in [-\theta , 1-\theta ]\) and \(u^{R}_{y}:=(u^{ R})' \in [-\theta , 1- \theta ]\) a.e., and
Let
and
If
then there exists a function \(u \in \mathcal{A}(R^{l_{x}, l_{y}})\) such that
-
(i)
\(u\) satisfies the boundary conditions on the left and right boundaries
$$ u(0,y)=u^{L}(y)\ \textit{and}\ \quad u(l_{x},y)=u^{R}(y) \qquad\textit{for all $y\in (0,l_{y})$,} $$ -
(ii)
\(u\) satisfies the boundary conditions on the top and bottom boundaries
$$ u(x,0)=u^{B}(x)\ \textit{and}\ u(x,l_{y})=u^{T}(x) \qquad \textit{for all $x\in (0,l_{x})$, and} $$ -
(iii)
with the linear interpolations given in (25) and (12), there holds
Remark 1
Explicit integration, using (25) and (i), immediately gives
The condition (28) can be replaced with
for a constant \(K > 0\), the value of \(\tilde{c}_{0}\) then depends on \(K\). The choice \(K = 1\) corresponds to (28).
Further, in (iii) the factors \(\omega ^{T}/\theta \) and \(\omega ^{B}/\theta \) can be replaced by \(\min \{\omega ^{T}/\theta ,\,L_{y}\}\) and \(\min\{\omega^{B}/\theta, L_{y}\}\), respectively.
The proof shows that we can choose \(\tilde{c}_{0}=144\).
Proof
We first construct in Step 1-4 an admissible function \(\tilde{u}\) satisfying (i),
and
and modify it close to the upper and lower boundaries in Step 5 to obtain a function as claimed. We describe the construction only on the right half of the rectangle \((l_{x}/2,l_{x})\times (0,l_{y})\), the construction in the other part can be done similarly.
Step 1: Geometry of the construction.
We decompose the rectangle in smaller rectangles, as illustrated in Fig. 2. In \(x\)-direction we use a geometrically refining decomposition. To shorten notation, we write \(\eta :=1/3\) and for \(i \in \mathbb{N}\) we set
Then
The decomposition in \(y\)-direction is more involved. In contrast to the decomposition used for \(\theta =\frac{1}{2}\) in [41, Lemma 2.3] and [17, Lemma 2.3], the separation points are not equally distributed in \((0, l_{y})\). We fix \(N\in \mathbb{N}\), \(N\ge 1\), chosen below (see (42)) and for \(i\in \mathbb{N}\) choose \(2^{i}N+1\) ordered points \(y^{i,k}\in [0,l_{y}]\) such that, roughly speaking, in the intervals \(\{x_{i}\}\times (y^{i,k},y^{i,k+1})\), the volume fraction of the minority variant \(\tilde{u}_{y}=1-\theta \) is of order \(\theta \). More precisely, we define
The function \(f\) can be seen as a measure of the portion of the minority variant in \(u^{L}\) and \(u^{R}\) in \((0,y)\). By the assumption \(u^{L}_{y}, u^{R}_{y}\in [-\theta ,1-\theta ]\) the function \(f\) is Lipschitz continuous with \(1\le f'\le 1+\frac{2}{\theta }\) almost everywhere, and in particular strictly monotonically increasing. From (28) and (24) we obtain \({\max \left \{ \left |u^{L}(l_{y})-u^{L}(0)\right |, \left |u^{R}(l_{y})-u^{R}(0) \right |\right \} }\leq \theta l_{y}\) and therefore
In particular, \(f:[0,l_{y}]\to [0,M]\) is bijective.
We now select decomposition points according to this density. Precisely, for \(i\in \mathbb{N}\) and \(k \in \{ 0, \dots , 2^{i}N\}\) we define \(y^{i,k}\) by
We observe that \(y^{i, 2k} = y^{i-1, k}\) for \(k \in \{ 0, \dots , 2^{i-1}N\}\), \(f(y^{i,k+1})-f(y^{i,k})=\frac{M}{2^{i}N}\) for all \(i\in \mathbb{N}\) and all \(k \in \{ 0,\dots , 2^{i}N-1\}\), and, since \(f'\ge 1\),
Step 2: Construction on \(\{x_{i}\}\times [0,l_{y}]\) .
For \(i\in \mathbb{N}\), let \(\tilde{u}(x_{i},\cdot ):(0,l_{y})\to \mathbb{R}\) be the unique continuous, piecewise affine function with the following properties (see Fig. 3):
-
(i)
\(\tilde{u}(x_{i},y^{i,k})=u^{l}(x_{i},y^{i,k})\) for all \(k\in \{0,\dots ,2^{i}N\}\), where \(u^{l}\) is the linear interpolation from (25); and
-
(ii)
for all \(k\in \{0,\dots ,2^{i}N-1\}\), there exists \(m^{i,k}\in [y^{i,k},y^{i,k+1}]\) such that
$$ \tilde{u}_{y}(x_{i},\cdot )= \textstyle\begin{cases} 1-\theta , &\quad \text{in }(y^{i,k},m^{i,k}), \\ -\theta ,&\quad \text{in }(m^{i,k},y^{i,k+1}). \end{cases} $$
This is possible since \(u^{l}_{y}\in [-\theta ,1-\theta ]\) (see Fig. 3). Note that
Recalling that \(\theta f'=3\theta + u^{R}_{y}+u^{L}_{y}\), and rearranging terms, we obtain
which yields, recalling the definition of \(y^{i,k}\) and (32),
The condition \(u^{l}_{y}\in [-\theta ,1-\theta ]\) leads to (see Fig. 3)
for \(y\in [y^{i,k},y^{i,k+1}]\). The difference between the first and the third expression is bounded by \(m^{i,k}-y^{i,k}\). Therefore, by (33),
Step 3: Construction in \((x_{i},x_{i+1})\times (0,l_{y})\) .
For \(i\in \mathbb{N}\), consider the points \(0=z^{i,0}< z^{i,1}<\cdots <z^{i,J_{i}}=l_{y}\) with
We now construct a continuous, piecewise affine function \(\tilde{u}\) on \((x_{i},x_{i+1})\times (0,l_{y})\) in the following (iterative) way (see Fig. 4). Let \(j\in \{0, \dots , J_{i}-1\}\), and assume that the construction on \((x_{i},x_{i+1})\times (0, z^{i,j})\) is done. By the construction in Steps 1 and 2 the functions \(\tilde{u}(x_{i},\cdot )\) and \(\tilde{u}(x_{i+1},\cdot )\) are affine on \((z^{i,j},z^{i,j+1})\).
-
(i)
If \(\tilde{u}_{y}(x_{i},\cdot )=\tilde{u}_{y}(x_{i+1},\cdot )\) on \((z^{i,j},z^{i,j+1})\) then we use the linear interpolation and set
$$ \tilde{u}(x,y):=\frac{x-x_{i}}{x_{i+1}-x_{i}}\tilde{u}(x_{i+1},y)+ \frac{x_{i+1}-x}{x_{i+1}-x_{i}}\tilde{u}(x_{i},y)\quad \text{ in } (x_{i},x_{i+1}) \times (z^{i,j},z^{i,j+1}). $$ -
(ii)
Assume now \(\tilde{u}_{y}(x_{i},\cdot )=-\theta \neq 1-\theta = \tilde{u}_{y}(x_{i+1}, \cdot )\) on \((z^{i,j},z^{i,j+1})\), the other case can be treated analogously. We construct a piecewise affine function such that \(\tilde{u}_{y}\) does not jump on \((x_{i},x_{i+1})\times \{z^{i,j}\}\). Precisely, if \(j=0\) or \(\lim _{y\nearrow z^{i,j}}\tilde{u}_{y}(x,y)=-\theta \) for \(x\in (x_{i},x_{i+1})\), then we set
$$ \tilde{u}(x, y):= \textstyle\begin{cases} (1-\lambda _{x})\tilde{u}(x_{i},z^{i,j}) + \lambda _{x}\tilde{u}(x_{i+1},z^{i,j}) -\theta (y - z^{i,j}), \\ \hfill \text{if }y\leq \lambda _{x}z^{i,j} +(1-\lambda _{x})z^{i,j+1}, \\ (1-\lambda _{x})\tilde{u}(x_{i},z^{i,j+1}) + \lambda _{x} \tilde{u}(x_{i+1},z^{i,j+1}) + (1- \theta )(y - z^{i,j+1}), \\ \hfill \text{otherwise}, \end{cases} $$where \(\lambda _{x}:=\frac{x-x_{i}}{x_{i+1}-x_{i}}\). If instead \(\lim _{y\nearrow z^{i,j}}\tilde{u}_{y}(x,y)=1-\theta \), we set
$$\begin{aligned} \tilde{u}(x, y):= \textstyle\begin{cases} (1-\lambda _{x})\tilde{u}(x_{i},z^{i,j}) + \lambda _{x}\tilde{u}(x_{i+1},z^{i,j}) +(1-\theta ) (y - z^{i,j}), \\ \hfill \text{if }y\leq (1-\lambda _{x}) z^{i,j} +\lambda _{x}z^{i,j+1}, \\ (1-\lambda _{x})\tilde{u}(x_{i},z^{i,j+1}) + \lambda _{x}\tilde{u}(x_{i+1},z^{i,j+1}) - \theta (y - z^{i,j+1}) \\ \hfill \text{otherwise}. \end{cases}\displaystyle \end{aligned}$$For later reference, we remark that this construction satisfies
$$ \tilde{u}_{x} \in \left \{ \frac{\tilde{u}(x_{i+1},z^{i,j})- \tilde{u}(x_{i},z^{i,j})}{x_{i+1}-x_{i}}, \frac{\tilde{u}(x_{i+1},z^{i,j+1})- \tilde{u}(x_{i},z^{i,j+1})}{x_{i+1}-x_{i}} \right \} $$which, since \(\tilde{u}_{y}(x_{i+1},\cdot )- \tilde{u}_{y}(x_{i}\cdot )=\pm 1\) in this interval, implies (with (33))
$$ \left |\tilde{u}_{x}(x,y)- \frac{\tilde{u}(x_{i+1},y)- \tilde{u}(x_{i},y)}{x_{i+1}-x_{i}}\right | \le \frac{z^{i,j+1}-z^{i,j}}{x_{i+1}-x_{i}} \le \frac{1}{x_{i+1}-x_{i}}\frac{5\theta l_{y}}{2^{i}N} $$(35)almost everywhere in \((x_{i},x_{i+1})\times (z^{i,j},z^{i,j+1})\).
By construction (see Fig. 4),
Step 4: Energy estimate for \(\tilde{u}\) .
Summing (36) over all \(i\in \mathbb{N}\), and inserting a factor of 2 for the other half of the rectangle,
It remains to estimate the elastic energy. To simplify notation, we set \(R_{i}:=(x_{i},x_{i+1})\times (0,l_{y})\) and introduce the linear interpolation in \((x_{i},x_{i+1})\),
Straightforward expansion and explicit integration shows, as in [17, Lemma 2.3], that
We start from the first term on the right hand side, and treat each subrectangle \((x_{i},x_{i+1})\times (z^{i,j}, z^{i,j+1})\) separately. By the construction from Step 3, there are two cases:
If \(\tilde{u}_{y}(x_{i},\cdot )=\tilde{u}_{y}(x_{i+1},\cdot )\) on \((z^{i,j},z^{i,j+1})\) then \(\tilde{u}=\tilde{u}^{i,l}\) in \((x_{i},x_{i+1})\times (z^{i,j},z^{i,j+1})\). Otherwise, \(\tilde{u}_{y}(x_{i},\cdot )=1-\theta \) or \(\tilde{u}_{y}(x_{i+1},\cdot )=1-\theta \) in \((z^{i,j},z^{i,j+1})\). By construction, there are at most \(2^{i+1}N\) such intervals (see Fig. 4), and by (33) for each of them \(z^{i,j+1}-z^{i,j}\leq \frac{5\theta l_{y}}{2^{i}N}\). Furthermore, using (35), for almost every \(y\in (z^{i,j},z^{i,j+1})\) we have
and hence
For the last term in (37), we use first that \(\tilde{u}^{i,l}-u^{l}\) is affine in \(x\)-direction in \((x_{i},x_{i+1})\times (0,l_{y})\) and then (34). Hence
Inserting (39) and (40) in (37) and summing over \(i\), we obtain (since \(\theta \leq 1/2\))
In order to balance this term and the estimate for \(|\tilde{u}_{yy}|\) we choose
Therefore, recalling that \((0,l_{x}/2)\times (0,l_{y})\) is treated symmetrically, we obtain (30), using that \(l_{y}\geq \varepsilon ^{1/3}\theta ^{-2/3}l_{x}^{2/3}\) implies that \(\varepsilon l_{x}\leq \varepsilon ^{2/3}\theta ^{2/3}l_{x}^{1/3}l_{y}\) and \(N \le 11 \varepsilon ^{-1/3} \theta ^{2/3} l_{x}^{-2/3} l_{y}\),
where in the last step we set \(\tilde{c}_{0}:=144\).
From (38) and Hölder’s inequality we obtain \(|\tilde{u} - \tilde{u}^{i,l}|\le \frac{5\theta l_{y}}{2^{i}N}\) in \(R_{i}\). Since \(\tilde{u}^{i,l} - u^{l}\) is affine in the \(x\) direction inside each \(R_{i}\), it attains its maximum either at \(x=x_{i}\) or at \(x=x_{i+1}\), and by (34) we obtain \(| \tilde{u}^{i,l} - u^{l}| \le \frac{5\theta l_{y}}{2^{i}N}\) in \(R_{i}\). With a triangular inequality and (42) we obtain (31),
Step 5: Conclusion.
It remains to modify \(\tilde{u}\) so that the boundary conditions on the top and bottom boundaries are fulfilled. We proceed as in [17, Lemma 2.6] and set
where \(\varphi ^{B}\), \(\eta ^{B}\) are the smallest and largest function compatible with \(u^{B}\) which have \(y\)-derivative in \([-\theta ,1-\theta ]\),
and correspondingly
By (28) we have \(|u^{T}-u^{B}|\le \theta l_{y}\) and therefore
For \(y=0\) we have \(\varphi ^{T}\le \eta ^{B}=\varphi ^{B}=u^{B}\), which implies \(u=u^{B}\), and correspondingly for \(y=l_{y}\). For \(x=l_{x}\) we have \(\tilde{u}(l_{x},y)=u^{R}(y)\) with derivative in \([-\theta ,1-\theta ]\), and recalling \(u^{B}(l_{x})=u^{R}(0)\) we obtain
The corresponding estimate holds for \(\varphi ^{T}\), \(\eta ^{T}\), and at \(x=0\). Therefore \(u\) satisfies the boundary conditions (i) and (ii).
The estimate on the energy follows by direct computation. Using that the construction of \(u\) from \(\tilde{u}\) creates at most two new interfaces, one obtains that the surface energy grows by at most \(2\varepsilon l_{x}\). By (31) and the definition of \(\omega ^{B}\) we have
so that \(\{\tilde{u}<\varphi ^{B}\}\cup \{ \eta ^{B}<\tilde{u} \}\subseteq (0,l_{x}) \times (0,\omega ^{B}/ \theta )\), and the same on the other side. The increase of the elastic energy in these strips is then estimated using Lemma 1 below. This proves (iii). □
In closing we recall the following result from [17, Lemma 2.5] that has been used in the final step.
Lemma 1
Let \(v, \varphi _{i}, \eta _{j} \in W^{1,2}(0, l_{x})\) be given such that the inequality \(\varphi _{i} \le v \le \eta _{j}\) for \(i = 1, \dots , n\) and \(j = 1, \dots , m\) at \(x=0\) and \(x=l_{x}\) holds. Then for
the following estimate holds
We remark that the statement in [17] misses the last term, which is irrelevant in the present situation since by construction \(\max \{\varphi ^{B}, \varphi ^{T}\}\le \min \{\eta ^{T}, \eta ^{B}\}\).
4 Global Scaling Laws
We discuss the global scaling laws (see Theorem 1) and then give a more precise characterization of the minimizers in the case of \(L_{x}\) large.
Proof of Theorem 1.
For the convenience of the reader, we give an explicit self-contained proof of the global scaling law in our setting. This is a simplified version of [19, Theorem 1.2] for \(\beta =\infty \).
Upper bound. The constructions are all based on Proposition 1.
If \(\varepsilon ^{1/3}\theta ^{-2/3}L_{x}^{2/3}\le L_{y}\) then setting \({u^{L}:= 0,u^{R}:= 0,u^{T}:= 0}\) and \({u^{B}:=0}\) in Proposition 1 we obtain a function which is zero on the boundary and has energy bounded by \(\tilde{c}_{0} \varepsilon ^{2/3}\theta ^{2/3}L_{x}^{1/3}L_{y}\).
Otherwise, we define \(l_{x}:=\varepsilon ^{-1/2}\theta L_{y}^{3/2}< L_{x}\), so that \(L_{y}= \varepsilon ^{1/3}\theta ^{-2/3}l_{x}^{2/3}\). We set \(u(x,y):=-\theta y\) on \([l_{x},L_{x})\times (0, L_{y})\), and extend it to the entire domain using Proposition 1 in \((0, l_{x})\times (0,L_{y})\) with \(u^{L}=0\), \(u^{B}=0\), \(u^{R}(y)=-\theta y\), and \(u^{T}(x)=-\theta L_{y} x/l_{x}\).
Lower bound. Fix \(u\in \mathcal{A}_{0}(R^{L_{x},L_{y}})\). Let \(\ell \in (0,L_{x}]\) and \(\lambda \in (0,1]\), chosen below. Then there is an interval \({J}\subseteq (0,L_{y})\) of length \(\lambda L_{y}\) such that
By the slicing theorem there is \(\bar{x}\in (0,\ell )\) such that \(u_{y}(\bar{x},\cdot )\in \{-\theta ,1-\theta \}\) \(\mathcal{L}^{1}\)-almost everywhere and
If \(u_{y}(\bar{x},\cdot )\) is not constant on \({J}\) then \(|u(\bar{x},\cdot )_{yy}|({J})\geq 1\) and
Otherwise \(u(\bar{x},\cdot )\) is affine on \({J}\). If \(u_{y}(\bar{x},\cdot )=-\theta \) on \({J}\), then by Jensen’s inequality and the boundary condition \(u(0,\cdot )=0\),
which gives
If \(u_{y}(\bar{x},\cdot )=1-\theta \) then we obtain a larger lower bound with \(\theta \) replaced by \(1-\theta \). Summarizing, for all \(\ell \in (0,L_{x}]\) and all \(\lambda \in (0,1]\), by (44) and (45),
If \(\varepsilon \leq \frac{\theta ^{2} L_{y}^{3}}{L_{x}^{2}}\) then we expect branching on the whole domain. This is reflected in the choice of the parameters \(\ell =L_{x}\) and \(\lambda =\theta ^{-2/3}\varepsilon ^{1/3}L_{x}^{2/3}L_{y}^{-1}\). If on the other hand \(\varepsilon > \frac{\theta ^{2} L_{y}^{3}}{L_{x}^{2}}\) then we choose \(\ell =\varepsilon ^{-1/2}\theta L_{y}^{3/2}\) and \(\lambda =1\). The result follows from (46). □
Remark 2
This argument also shows that the scaling of the bound in (9) is optimal for small \(x\). Fix any \(l_{x}\le \varepsilon ^{-1/2}\theta L_{y}^{3/2}\), and set \(\lambda =c\theta ^{-2/3}\varepsilon ^{1/3}l_{x}^{2/3}L_{y}^{-1}\). If \(c\) is chosen sufficiently small, then the option \(I\ge \varepsilon l_{x}/(2\lambda ) =(2c)^{-1}\varepsilon ^{2/3} \theta ^{2/3} l_{x}^{1/3} L_{y}\) is incompatible with the upper bound on the energy. Therefore (44) does not hold, and there is a segment of length \(\lambda L_{y}\) on which \(u\) is affine, with derivative \(1-\theta \) or \(-\theta \). This implies that \(\|u(\bar{x}, \cdot )\|_{L^{\infty }(J)} \ge \frac{1}{2} \theta \lambda L_{y} = \frac{1}{2} c \varepsilon ^{1/3}\theta ^{1/3}l_{x}^{2/3}\).
For \(L_{x} > \varepsilon ^{-1/2}\theta L_{y}^{3/2}=:l_{x}\) the competitor for the upper bound constructed in the proof of Theorem 1 is affine on \((l_{x}, L_{x})\times (0, L_{y})\). Hence, the energy vanishes on \((l_{x}, L_{x})\times (0, L_{y})\). We show that this is also the case for a minimizer, up to a multiplicative factor in the definition of \(l_{x}\). The proof combines the scaling law with a result from [27, Sect. 4] that we present in this simplified setting for completeness.
Lemma 2
Let \(\varepsilon , L_{x}, L_{y}>0\), and \(\theta \in (0,\frac{1}{2}]\). Let \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) be a minimizer of \(I(\cdot , R^{L_{x}, L_{y}})\) on \(\mathcal{A}_{0}(R^{L_{x}, L_{y}})\). If \(L_{x} > c \varepsilon ^{-1/2}\theta L_{y}^{3/2} =: l_{x}\), then \(u\) is affine on \([l_{x}, L_{x})\times (0, L_{y})\), where \(c > 0\) is the constant introduced in Theorem 1.
Proof
Assume first that there is \(\bar{x} \in (0, L_{x})\) such that \(u(\bar{x}, \cdot )\) is affine, with \(u_{y}(\bar{x},\cdot )\in \{-\theta ,1-\theta \}\). We then consider the competitor
It is easy to see that \(v\in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\), and that
Since \(u\) is a minimizer, we deduce \(u_{x}=0\) for \(x\ge \bar{x}\), and in particular \(u=v\) (cf. [27, Sect. 4]).
Let \(\nu _{j} \rightarrow 0\), \(\nu _{j} > 0\). If there exists no \(x\in (0,l_{x} + \nu _{j})\) such that \(u(x, \cdot )\) is affine then we obtain the contradiction
where we have used the definition of \(l_{x}\) and the upper bound from Theorem 1. Hence, there exists a sequence \(x_{j} \in (0, l_{x} + \nu _{j})\), \(j\in \mathbb{N}\) such that \(u\) is affine on \((x_{j}, L_{x})\times (0, L_{y})\) for all \(j\in \mathbb{N}\), and hence on \((l_{x},L_{x})\times (0,L_{y})\). Since \(u\) is continuous, it is affine on the closure of this set. □
5 Local in \(x\) Energy Scaling Law
In this section we provide a local bound similar to the scaling law in Theorem 1 on rectangles \((0,l_{x})\times (0,L_{y})\) for \(l_{x} \in (0, L_{x})\). In particular, we prove that any minimizer \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) restricted to a subrectangle \(R^{l_{x}, L_{y}}\) obeys the same energy scaling as a minimizer on \(R^{l_{x}, L_{y}}\). The case \(\theta = 1/2\) was first presented by Kohn and Müller in [41, Theorem 2.6]. The results and proofs of this section for \(\theta \in (0,1/2]\) are part of the thesis [25].
Theorem 4
Local energy bound
Let \(\varepsilon , L_{x}, L_{y}>0\), and \(\theta \in (0,\frac{1}{2}]\). Suppose that \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) is a minimizer of \(I(\cdot , R^{L_{x}, L_{y}})\). Further, let \(l_{x} \in (0, \min \{ \varepsilon ^{-1/2}\theta L_{y}^{3/2}, L_{x}\})\) and assume \(\vert u(l_{x}, L_{y})-u(l_{x},0)\vert \le \theta L_{y}\). Then
holds for a universal constant \(C\).
Remark 3
In analogy to Remark 1, the assumption \(\vert u(l_{x}, L_{y}) - u(l_{x}, 0) \vert \le \theta Ly\) can be replaced with the weaker condition
for some constant \(K > 0\). Note, that we do not need the upper bound \((1-\theta )L_{y}\) as in Remark 1 since we only need to construct an admissible function which is equal to \(u(l_{x}, \cdot )\) on \(\{l_{x}\}\times (0, L_{y})\) and equal to zero on \(\{0\}\times (0, L_{y})\).
The lower bound of (47) immediately follows from the scaling law, see Theorem 1. The proof of the upper bound in (47) is instead based on a result about the equipartition of energy. Precisely, we show that the horizontal distribution of the terms \(u_{x}^{2}\) and \(\varepsilon \vert u_{yy}\vert \) of a minimizer is the same, in the sense that there is \(\tau \in \mathbb{R}\) with
Lemma 3
Equipartition of energy
Let \(\varepsilon , L_{x}, L_{y}>0\), and \(\theta \in (0,\frac{1}{2}]\). Let \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) be a minimizer of \(I(\cdot , R^{L_{x}, L_{y}})\) on \(\mathcal{A}_{0}(R^{L_{x}, L_{y}})\). Then the following statements are true:
-
1.
There is \(\sigma \in L^{1}((0,L_{x}))\) such that
$$ \varepsilon |u_{yy}|(E\times (0,L_{y}))=\int _{E} \sigma \, \mathrm{d}\mathcal{L}^{1} $$for all open sets \(E\subseteq (0,L_{x})\).
-
2.
There exists \(\tau \in \mathbb{R}\) such that
$$ \sigma (x)= \tau + \int _{0}^{L_{y}} u_{x}^{2}(x,y) \,\mathrm{d}y $$for almost every \(x \in (0, L_{x})\).
-
3.
One has
$$ \vert \tau \vert \le c \varepsilon ^{2/3} \theta ^{2/3} L_{x}^{-2/3} L_{y}, $$where \(c > 0\) is the constant from Theorem 1.
Proof
Assertions (i) and (ii) can be proven by considering inner variations \(v_{\rho }(x):=u(x+\rho \varphi (x),y)\), as discussed in [41, Lemma 2.4]. In order to prove the bound on \(\tau \) we observe that
which implies
The assertion follows then from the upper bound in Theorem 1. □
The construction of an energy efficient competitor on a subrectangle has already been done in the last subsection, see the proof of Proposition 1. This construction is a crucial ingredient in the following proof.
Proof of Theorem 4.
Let \(u\in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) be a minimizer, \(\tau \) as in the equipartition result (Lemma 3), \(l_{x}\in (0,L_{x})\). We have
By Hölder’s inequality,
By Proposition 1, applied with \(u^{T}\) and \(u^{B}\) equal to the linear interpolation on \((0,l_{x})\), there is \(v\in \mathcal{A}_{0}(R^{l_{x},L_{y}})\) such that \(v=u\) for \(x=l_{x}\) and
Let \(\tilde{u}\) be equal to \(v\) on \((0,l_{x})\), and equal to \(u\) on \([l_{x},L_{x}]\). Then minimality of \(u\) leads to
which implies
Inserting the bound on \(\tau \) from Lemma 33 and using \(l_{x}\le L_{x}\) concludes the proof of the upper bound. The lower bound follows from Theorem 1. □
6 Local in \(x\) and \(y\) Energy Scaling Law
This section is devoted to the proof of the local energy bounds and pointwise bounds for minimizers as given in Theorem 3. We follow the general lines of [17] with several changes to address the additional difficulties for \(\theta \ll 1\).
Let us briefly explain where the main difficulties arise compared to the equal volume fraction case. An important ingredient in [17] is an interpolation inequality for functions \(v\in W^{1,2}(0,h)\) with \(\vert v' \vert \le \alpha \) for some \(\alpha >0\). It states that
In our setting, we would essentially need a replacement for functions with \(v_{y}\in [-\theta ,1-\theta ]\). Having periodic laminates in mind, we would aim for an estimate with \(\alpha \) replaced by \(\theta \). Precisely, for the function
we have for all \(\theta \in (0,1/2]\),
i.e.,
However, such an estimate does not hold for general functions \(u\) with \(u_{y}\in [-\theta ,1-\theta ]\): Consider for example,
Then
We point out that the estimate (48) with \(\alpha =1\) is not sufficient to obtain the expected scaling in \(\theta \), for details see [43]. The estimate is replaced by Lemma 4, which however does not cover the entire set. Therefore a different treatment of the boundary region is needed.
Lemma 4
Pointwise estimate of an admissible function
Let \(I\subseteq \mathbb{R}\) be an interval, \(f\in W^{1,1}(I)\) with \(f'\ge -\theta \) almost everywhere for some \(\theta >0\). Let \(\delta >0\) and \(y\in I\). Then, choosing the continuous representative,
Proof
We start with the first bound. If \(f(y)\le \delta \theta \), we are done. If \(f(y)> \delta \theta \), we use \(f(t)\ge f(y)-(t-y)\theta \ge f(y) - \delta \theta \ge 0\) for \(t\in (y,y+\delta )\subseteq I\), so that
which implies
The second estimate follows by applying this one to \(y\mapsto -f(-y)\). □
One important strategy in the proof of Theorem 3 will be to study the local behavior of the excess elastic energy of an admissible function \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\), in the sense of Proposition 1. We denote the localization of this modified functional to rectangles \((0,l_{x})\times (a,b)\subseteq R^{L_{x},L_{y}}\) by
where the function \(u^{l}\) is the linearization of \(u\) on \(R^{l_{x}, L_{y}}\),
Lemma 5
Estimate for the excess elastic energy
Let \(c_{0}, c_{1}, c_{2}, k_{0}>0\), with \(c_{1}\geq 1\), \(2^{1/3} k_{0} \le c_{0}\) and
where \(\tilde{c}_{0}\) is the constant from Proposition 1.
Let \(\varepsilon ,l_{x}>0\), \(\theta \in (0,\frac{1}{2}]\), \(A,B\in \mathbb{R}\) with \(B\ge A+c_{1} \varepsilon ^{1/3} \theta ^{-2/3}l_{x}^{2/3}\), and let \(u \in \mathcal{A}_{0}((0,l_{x}+\delta )\times (A-\delta ,B+\delta ))\) be a local minimizer, for some \(\delta >0\). Assume
and
Then
The proof follows the lines of [17, Proposition 2.12], using Proposition 1 instead of [17, Proposition 2.6]. However, the fact that we are working with arbitrary \(\theta \) renders the \(L^{2}\)-\(L^{\infty }\) estimate more difficult, hence we choose a different procedure to estimate the coefficients \(\omega ^{T}\) and \(\omega ^{B}\) (see (26) and (27) respectively).
Proof
Step 0. Preliminaries.
For brevity we denote by \(h_{\mathrm{min}}:=c_{1} \varepsilon ^{1/3} \theta ^{-2/3} l_{x}^{2/3}\) the minimal height of the rectangles considered.
We shall construct competitors using Proposition 1. To estimate the coefficients \(\omega ^{B}\) and \(\omega ^{T}\) in Proposition 1 we notice that the fundamental theorem of calculus, Hölder’s inequality, \(|u^{l}|(x,y)\le |u|(l_{x},y)\) and (51) imply that for any \(y_{*}\in [A,B]\) we have
In particular, for \(y_{*}=A\) and \(y_{*}=B\), respectively, using (52) we obtain
We shall use a comparison with functions constructed in Proposition 1 to obtain bounds on the energy of \(u\) on subsets of its domain. Specifically, if \(v\in {\mathcal{A}}_{0}((0,l_{x})\times (a,b))\) for some \((a,b)\subseteq (A,B)\), the fact that \(u\) is local minimizer implies
To see this, it suffices to consider a competitor \(w\) which coincides with \(u\) outside \((0,l_{x})\times (a,b)\), and with \(v\) inside. The possible jump of \(w_{y}\) on the horizontal boundaries gives a contribution not larger than \(2\varepsilon l_{x}\).
Finally, we remark for later reference that the assumption \(2^{1/3} k_{0}\le c_{0}\) and (50) imply
as well as
and, using that (57) implies \(\frac{2 (1+2c_{1}c_{2}+(2k_{0})^{1/2})k_{0}}{c_{1}}\le k_{0}\),
Step 1. We prove (53) in the case that \(a=A\) or \(b=B\).
We assume \(a=A\) and consider the function
If \(f(y)< 0\) for all \(y\) we are done. If this is not the case, we define
Since \(y\mapsto \beta _{u}(l_{x}, A, y)\) is nondecreasing, necessarily \(f(\tilde{y})\ge 0\).
We first apply Proposition 1 on the rectangle \((0,l_{x})\times (A,B)\), which is admissible since (54), (55) and (58) imply \(|u(x,A)|, |u(x,B)|\le \frac{1}{2} \theta h_{\mathrm{min}}\le \frac{1}{2} \theta l_{y}\), where we write for brevity \(l_{y}:=B-A\). We obtain a function \(v\in \mathcal{A}_{0}((0,l_{x})\times (A,B))\) which coincides with \(u\) on the boundary and, using (55) and (52), obeys
With \(l_{y}\ge h_{\mathrm{min}}\), \(\varepsilon l_{x}\le \varepsilon l_{x} \frac{l_{y}}{h_{\mathrm{min}}}=c_{1}^{-1} \varepsilon ^{2/3}\theta ^{2/3}l_{x}^{1/3}l_{y}\) and (50), we obtain
Using (56) we get \(\beta _{u}(l_{x},A,B)< k_{0} \varepsilon ^{2/3}\theta ^{2/3} l_{x}^{1/3}l_{y}\) and therefore \(f(B)<0\), which implies \(\tilde{y}< B\).
Assume for a moment that there is a sequence \(y_{j}\in (\tilde{y}, B)\), \(y_{j}\to \tilde{y}\), such that
(this condition as usual includes existence of the integral). By (54), this implies
As above, with (58) this leads to \(|u(x,y_{j})|\le \frac{1}{2} \theta h_{\mathrm{min}}\) for all \(x\), hence (28) holds. We use Proposition 1 on \((0,l_{x})\times (A,y_{j})\) with (55) and (52) at \(y=A\), (61) and (62) at \(y=y_{j}\), and obtain, recalling \({\tilde{y}-A} \ge h_{\mathrm{min}}\), that there is a competitor \(v\) with
where in the last step we used the average of (50) and (57). Recalling (56) and monotonicity of \(\beta _{u}(l_{x},A,\cdot )\), this implies
for all \(j\). Taking \(j\to \infty \) leads to \(f(\tilde{y})<0\), against the definition of \(\tilde{y}\) (see (60)). Therefore, no sequence as in (61) exists. Hence, there is \(y_{*}>\tilde{y}\) such that
and recalling the definition of \(f\) we obtain
against the definition of \(\tilde{y}\) (see (60)). Therefore \(f< 0\) everywhere and the proof of Step 1 for \(a=0\) is concluded. The case \(b=B\) is identical, working on intervals \([y,B]\) instead of \([A,y]\).
Step 2. We prove (53) for \(a>A\) and \(b< B\).
The argument is similar to the one of Step 1. Fix \(a,b\in (A,B)\) with \(b-a\ge h_{\mathrm{min}}\) and let \(h_{\mathrm{max}}:=\min \{{a+b-2A},{ 2B-(a+b)}\}\ge h_{\mathrm{min}}\). We define \(g :[h_{\mathrm{min}}, h_{\mathrm{max}}] \rightarrow \mathbb{R}\),
If \(g<0\) everywhere we are done (set \(h:=b-a\)). Otherwise, we set
As above, since \(h\mapsto \beta _{u}(l_{x},\frac{a+b-h}{2},\frac{a+b+h}{2})\) is nondecreasing we obtain \(g(\tilde{h})\ge 0\). By Step 1 we obtain \(g(h_{\mathrm{max}})<0\), so that necessarily \(\tilde{h}< h_{\mathrm{max}}\). The proof proceeds then similar to the one of Step 1. Assume first that there is a sequence \(h_{j}\in (\tilde{h},h_{\mathrm{max}})\) such that
for all \(j\). By (54), this implies
With (59) and \(|u(x,\frac{a+b\pm h_{j}}{2})| \le \omega ( \frac{a+b\pm h_{j}}{2})\) we obtain \(|u(x,\frac{a+b\pm h_{j}}{2})| \le \frac{1}{2} \theta h_{\mathrm{min}}\), hence also in this case (28) holds. Using Proposition 1 on \((0,l_{x})\times ((a+b-h_{j})/2,(a+b+h_{j})/2)\) and \(h_{j}\ge h_{\mathrm{min}}\) we obtain a competitor \(v\) with
where in the second step we used (57). As above this implies, using monotonicity of \(h\mapsto \beta _{u}(l_{x},\frac{a+b-h}{2},\frac{a+b+h}{2})\) and then (56),
Taking \(j\to \infty \) leads to \(g(\tilde{h})< 0\), against the definition of \(\tilde{h}\). Therefore no such sequence exists, and there is \(h_{*}\in (\tilde{h},h_{\mathrm{max}})\) such that
for a.e. \(h\in (\tilde{h}, h_{*})\), so that
against the definition of \(\tilde{h}\). Therefore \(g< 0\) everywhere and the proof is concluded. □
Lemma 6
Under the same assumptions as in Lemma 5, if additionally
and
then the pointwise estimate
holds for all \(x\in [\phi l_{x},l_{x}]\) and \(y\in [A,B]\).
We remark that (64) implies in particular \(|u|(\phi l_{x},y)\le c_{1} c_{2} \varepsilon ^{1/3}\theta ^{1/3} ( \phi l_{x})^{2/3}\), which is a key estimate for the inductive proof below.
Proof
We first remark for later reference that the assumptions on the constants imply
and
We write as above \(h_{\mathrm{min}}:=c_{1} \varepsilon ^{1/3} \theta ^{-2/3} l_{x}^{2/3}\). Fix some \(x\in [\phi l_{x}, l_{x}]\), and let \(\delta := (k_{0}x/c_{1}^{2} l_{x})^{1/3}\), both fixed for the entire proof. Note that \(\delta \in (0,1]\) by (63) and \(x\le l_{x}\). Pick any \(y\in [A,B]\). If \(y< B-\delta h_{\mathrm{min}}\), then by Lemma 4 applied to the map \(u(x,\cdot ):[A,B]\to \mathbb{R}\) we obtain
Since \(u^{l}(x,t)=\frac{x}{l_{x}} u(l_{x},t)\), the triangle inequality in \(L^{2}\) gives
We choose an interval \(J\subseteq [A,B]\) of length \(h_{\mathrm{min}}\) which contains \((y,y+{\delta h_{\mathrm{min}}})\) (this is possible since \(\delta \le 1\) and \(h_{\mathrm{min}}\le {B-A}\)). By Lemma 5,
so that with Hölder’s inequality we obtain
Inserting this estimate and assumption (51) in (67) gives
The choice \(\delta = (k_{0}x/c_{1}^{2} l_{x})^{1/3}\) balances the second and the third term when replacing \(\varepsilon \) using the definition of \(h_{\mathrm{min}}\). Using \(x\ge \phi l_{x}\) in the last term,
With (65), the estimate
follows. Assume now \(y\in [B-\delta h_{\mathrm{min}},B]\). Lemma 4 applied to the map \(u(x,\cdot )\) gives
The argument then proceeds as above, and leads to
It remains to deal with the two boundary regions. Assume that \(y\in [{B-\delta h_{\mathrm{min}},B}]\), which implies \({B-y}\le k_{0}^{1/3} c_{1}^{1/3}\varepsilon ^{1/3}\theta ^{-2/3}x^{1/3}l_{x}^{1/3}\). Assumption (52) and Hölder’s inequality imply
and using as above \(u^{l}(x,y)=\frac{x}{l_{x}}u(l_{x},y)\) and assumption (51) we obtain
Since \(u_{y}\ge -\theta \) almost everywhere and \(\phi l_{x}\le x\),
Using (66) this leads to the desired bound.
Finally, for \(y\in [A,A+\delta h_{\mathrm{min}}]\) we analogously obtain
Recalling (68) and (69), the proof is concluded. □
We are now ready to prove the main result of this section.
Proof of Theorem 3.
The proof consists of four steps, where in the first three we assume \(l_{x}< L_{x}\). First, we prove two local bounds on \(u\) and \(\beta _{u}\) via induction and the two previous Lemmas. Afterwards, we show that they imply the claim of Theorem 3. In the third step, we show how the constants can be chosen. In a last step, the case \(l_{x}=L_{x}\) is treated.
For the first two steps we assume that there are constants \(c_{0}, c_{1}, c_{2}, k_{0}>0\), \(\phi \in (0,\frac{1}{8}]\) such that the assumptions of Lemma 5 and 6 hold and additionally
and
For \(n\in \mathbb{N}\) we set \(l_{x,n}:=\phi ^{n}l_{x}\), \(h_{n}:=\varepsilon ^{1/3}\theta ^{-2/3}l_{x,n}^{2/3}\), \(r_{0}:=2\eta L_{y}\), and for \(n\ge 1\)
where in the last step we used \(\phi \le 1/8\) and (6). We denote by \(u^{l}_{n}\) the linear interpolation on \((0, l_{x,n})\), defined as usual by \(u^{l}_{n}(x,y):=\frac{x}{l_{x,n}} u(l_{x,n},y)\), as in the definition of \(\beta _{u}(l_{x,n},\cdot ,\cdot )\).
Step 1. We prove by induction the following two statements:
and
We start with \(n=0\), and refer to Fig. 5 for a sketch of the geometry. By assumption (8) and Fubini’s theorem there is \(a_{*} \in (\eta L_{y}, 2\eta L_{y})\) with
and analogously \(b_{*}\in ((1-2\eta )L_{y},(1-\eta )L_{y})\).
We first apply Lemma 5 with \(A:=a^{\ast }\), \(B:=b^{\ast }\), and some \(0<\delta <{\min \{\eta L_{y},L_{x}-l_{x}\}}\). Condition (51) follows from assumption (7), condition (52) from the choice of \(a_{*}\) and \(b_{*}\) and (70). We obtain that for any interval \((a,b)\subseteq (a_{*}, b_{*})\) with \(b-a\ge c_{1}h_{0}\) one has
which proves (72) for \(n=0\). Next we use Lemma 6 with the same choices to obtain
which proves (73) for \(n=0\) and concludes the initial step of the induction.
Assume (72) and (73) hold for some index \(n\ge 0\). Using (72) with \(a=r_{n}\), \(b=r_{n}+c_{1}h_{n}\) and Fubini’s theorem we see that there is \(a_{n} \in (r_{n}, r_{n}+c_{1}h_{n})=(r_{n},r_{n+1})\) so that
and analogously \(b_{n}\in (L_{y}-r_{n+1}, L_{y}-r_{n})\). By the properties of the linearization,
and analogously for \(b_{n}\). We now apply Lemma 5 with \(l_{x}=l_{x,n+1}\), \(A:=a_{n}\), \(B:=b_{n}\) and some \(0<\delta <r_{n}\). Condition (51) follows from (73) with \(x=l_{x,n+1}\), condition (52) from (74) and (71). We obtain that for any interval \((a,b)\subseteq (a_{n}, b_{n})\) with \(b-a\ge c_{1}h_{n+1}\) one has
Since \((r_{n+1}, L_{y}-r_{n+1})\subseteq (a_{n},b_{n})\), this proves (72) for \(n+1\).
Next we use Lemma 6 with the same choices to obtain
which proves (73) for \(n+1\).
This concludes the proof of (72) and (73).
Step 2. We show that (72) and (73) imply the assertion of the Theorem. We start with (9). Let \((x,y)\in (0,l_{x}]\times [3\eta L_{y}, (1-3\eta )L_{y}]\). Since \(x>0\), there is \(n\in \mathbb{N}\) such that \(l_{x,n+1}< x\le l_{x,n}\). The assertion with \(d_{1}:=\frac{c_{1}c_{2}}{\phi ^{1/3}} \) follows from (73) using \(x\le l_{x,n}=l_{x,n+1}/\phi \) and recalling that \(r_{n}\le {\frac{8}{3}}\eta L_{y}{\le 3\eta L_{y}}\), and correspondingly \(L_{y}-{r_{n}}\le {\frac{8}{3}}\eta L_{y}\).
Now we turn to (10). Let \(l\in (0,l_{x}]\), \((a,b)\) as in the statement of the theorem. Choose \(n\) such that \(l_{x,n+1}< l\le l_{x,n}\). Then, recalling the definition of \(\beta _{u}\) and of the linear interpolation,
If we can choose \(\phi \ge \frac{1}{8}\), then \(b-a \ge 4c_{1} \varepsilon ^{1/3}\theta ^{-2/3}l^{2/3} \ge c_{1}h_{n}\), so that estimating the two terms with (72) and (73) leads to
which concludes the proof, with \(d_{2}:=k_{0} \phi ^{-1/3} + c_{1}^{2}c_{2}^{2} \phi ^{-1}\).
Step 3. We choose the constants.
We are given \(k_{1}> 0\), \(\eta \in (0,\frac{1}{6})\), and \(\tilde{c}_{0}\in [1,\infty )\) from Proposition 1. We first set \(\phi :=\frac{1}{8}\) and, for some \(c_{0}>0\) chosen below,
so that (71) and \(c_{0}\ge 2^{1/3}k_{0}\) are satisfied. With this definition, (50) reduces to
We set
and assume that
so that the first and third terms of the left hand side of (75) is at most \(1/4\) each. This also implies \(c_{0}\ge 1\), so that the last term is not larger than the second. Therefore to fulfill (50) it suffices to ensure that
In turn, the assumptions of Lemma 6 are true if we ensure
We finally set
so that also (70) is automatically enforced, and
Here, we used that \(8(1+c_{0}^{1/2})\phi ^{-1/3}\geq \max \{1,k_{0}^{1/2}\}\), and we remark that \(c_{0}\) (and hence \(k_{0}\) and \(c_{1}^{*}\)) continuously depend on \(k_{1}\) and \(\eta \).
Step 4. The case \(l_{x} = L_{x}\) .
We want to use the continuity of \(u\) and the fact that we have already proven the statement for \(l \in (0, L_{x})\). Our goal is to prove the estimates of Step 2, for all constants satisfying the conditions of Step 3.
Let \(k_{1} > 0\) and \(\eta \in (0, \frac{1}{6})\) be given and let \({c_{1}^{*}}, c_{2}, \tilde{c}_{0} , c_{0}\) and \(\phi \in (0,1)\) be chosen as in Step 3. Moreover, we assume that \(c_{1}\ge c_{1}^{*}\) is such that (6) holds, that for all \(y\in [\eta L_{y}, (1-\eta ) L_{y} ]\)
Note, that the maps \(k_{1} \mapsto c_{1}^{*}(c_{0}(k_{1}))\) and \(k_{1} \mapsto k_{0}(c_{0}(k_{1}))\) are continuous. We introduce the slightly changed constants \(k_{1,{{j}}} \coloneqq k_{1} + \frac{1}{{{j}}}\), \(k_{0,j} \coloneqq k_{0}(c_{0}(k_{1,j})) \) and \(c_{1,{{j}}} \coloneqq {\max \{c_{1}+\frac{1}{{{j}}}, c_{1}^{*}(c_{0}(k_{1,{{j}}})) \}} \) for \({{j}}\in \mathbb{N}\), which satisfy the condition from Step 3. Further, for large \({{j}}\) a weaker version of (6) holds, namely,
so that the condition \(r_{n}\le \frac{8}{3} \eta L_{y}\) at the beginning of Step 2 is replaced by \(r_{n}\le (3-\frac{1}{5})\eta L_{y}\). By Hölder-continuity of \(u\) (see Lemma 7 below), there exists \(\delta _{{j}}\in (0, L_{x})\) such that
holds for all \(l\in (L_{x} - \delta _{{j}}, L_{x})\) and \(y\in [\eta L_{y}, (1-\eta )L_{y}]\). Let \(x\in (0, L_{x})\). For \({{j}}\) sufficiently large we have \(x\le L_{x}-\delta _{{j}}\), and by Step 2 we conclude
where \(d_{1,{{j}}}\coloneqq \frac{c_{1,{{j}}}c_{2}}{\phi ^{1/3}}\), for all \(y \in [3\eta L_{y}, (1-3\eta )L_{y}]\). Taking the limit \({{j}}\to \infty \) the same holds with \(d_{1}\) instead of \(d_{1,{{j}}}\), and by continuity of \(u\) we obtain (9).
Let now \(l\in (0, L_{x})\) and \((a,b) \subseteq (3\eta L_{y}, (1-3\eta )L_{y})\) with \(b-a \geq 4 c_{1}\varepsilon ^{1/3}\theta ^{-2/3} l^{2/3}\). For \({{j}}\) large enough we can choose \(a_{j},b_{j}\) with \((a,b)\subseteq (a_{j},b_{j})\subseteq ((3-\frac{1}{5})\eta L_{y}, (1-(3- \frac{1}{5})\eta )L_{y})\), \(b_{j}-a_{j} \geq 4 c_{1,{{j}}}\varepsilon ^{1/3}\theta ^{-2/3} l^{2/3}\), and \(b_{j}\to b\), \(a_{j}\to a\). By Step 2 we conclude, for any \({{j}}\) sufficiently large,
where \(d_{2,{{j}}} \coloneqq {k_{0,{{j}}}}\phi ^{-1/3} + c_{1,{{j}}}^{2} c_{2}^{2} \phi ^{-1}{\to d_{2}}\) as \({{j}}\to \infty \). Taking \({{j}}\to \infty \) in (79) we obtain (10) for all \(l< L_{x}\), and by continuity of \(l\mapsto I(u,(0,l)\times (a,b))\) also for \(l=L_{x}\). □
Remark 4
We recall that the parameter \(\eta \) is not necessary in the setting of [17]. Indeed, the assumptions on the top and bottom boundary conditions considered there in particular allow to choose \(a_{n}=0\) and \(b_{n}=L_{y}\) for all \(n\in \mathbb{N}\) in Step 1 of the proof, using in Lemma 5 that \(u\) is a minimizer on \(R^{l_{x},L_{y}}\) subject to full Dirichlet boundary conditions, which renders the extension of the domain in terms of \(\delta \) unnecessary.
7 Asymptotic Self-Similarity of a Minimizer
We now turn to the proof of Theorem 2. For the proof it is useful to show that the minimizer \(u\) is uniformly continuous. Indeed, the anisotropic structure of \(\mathcal{A}\) implies Hölder-continuity with exponent \(1/3\), see [47, Lemma 3]. For completeness we recall the self-contained argument of this well-known fact.
Lemma 7
The space \(X(L_{x},L_{y}):=\{u\in W^{1,2}(R^{L_{x},L_{y}}): u_{y}\in L^{\infty }(R^{L_{x},L_{y}}) \}\) is continuously embedded in \(C^{1/3}(R^{L_{x},L_{y}})\).
Proof
After a linear change of variables we can assume \(R^{L_{x},L_{y}}=R:=(0,1)^{2}\). It suffices to show that there is \(c>0\) such that for any \(u\in X(1,1)\) for almost every \(p_{0}, p_{1}\in R\) we have
To see this, let \(M:=\|u_{y}\|_{L^{\infty }(R)}+\|u_{x}\|_{L^{2}(R)}\). For \(\mathcal{L}^{2}\)-almost every \(p_{0}=(x_{0},y_{0})\) the function \(u(x_{0},\cdot )\) has an \(M\)-Lipschitz representative which has a Lebesgue point at \(y_{0}\), and the same for \(p_{1}=(x_{1},y_{1})\). For \(\ell \in (0,1]\) chosen below, with \(\ell \ge |y_{0}-y_{1}|\), let \(I_{\ell }\) be an interval of length \(\ell \) such that \(y_{0},y_{1}\in I_{\ell }\subseteq [0,1]\). Choose \(y_{2}\in I_{\ell }\) such that \(u(x_{0},\cdot )\) and \(u(x_{1},\cdot )\) have a Lebesgue point at \(y_{2}\) and
so that by Hölder’s inequality \(|u(x_{0},y_{2})-u(x_{1},y_{2})|\le |x_{0}-x_{1}|^{1/2} M \ell ^{-1/2}\). We then estimate
Choosing \(\ell :=\min \{1,|p_{0}-p_{1}|^{1/3}\}\) concludes the proof of (80). □
The key ingredient in the proof of the strong convergence of the blow-ups is a construction that permits to continuously modify a function in \(\mathcal{A}_{0}\) by shifting the interfaces. The aim is to show that a small change in the boundary values corresponds to a small change in energy. We present here the construction from [17, Lemma 3.6], adding some detail and extending it to the case of general \(\theta \). This requires, as in other parts of this paper, a different treatment of the region where \(u_{y}=1-\theta \) and the one where \(u_{y}=-\theta \), using somewhat different estimates.
Lemma 8
For any \(\hat{c}>0\) there are \(c_{y},c_{I}>0\) such that the following holds. Let \(\varepsilon >0\), \(\theta \in (0,1/2]\), \(l_{x},l_{y}>0\), \({u\in \mathcal{A}_{0}}(R^{l_{x},l_{y}})\), \(v^{T}\in W^{1,2}((0,l_{x}))\) with \(v^{T}(0) =0\), and set \(h_{0}:=\varepsilon ^{1/3}\theta ^{-2/3}l_{x}^{2/3}\). Assume \(l_{y}\ge c_{y} h_{0}\),
and
Then there is \(v\in \mathcal{A}_{0}(R^{l_{x},l_{y}})\) such that \(v(\cdot ,0)=u(\cdot ,0)\), \(v(\cdot ,l_{y})=v^{T}\), \(v_{y}(\cdot , l_{y})=u_{y}(\cdot , l_{y})\), \(v_{y}(\cdot , 0)=u_{y}(\cdot , 0)\) (in the sense of traces), and
where
If \(v^{T}(l_{x})=u(l_{x},l_{y})\), then additionally \(v(l_{x},\cdot )=u(l_{x},\cdot )\).
Proof
We write for brevity \(R:=R^{l_{x},l_{y}}\), \(u^{T}(x):=u(x,l_{y})\) and \(u^{B}(x):=u(x,0)\). We choose \(c_{y}:=\max \{3, 6\hat{c}\}\) and notice that \(u^{T}(0)=v^{T}(0)=0\), Hölder’s inequality and (85) imply
Step 1. Shifting the interfaces in the correct way.
One key ingredient in the proof is that (for a.e. \(x\)) the value \(u^{T}(x)-u^{B}(x)\) is in one-to-one correspondence with the measure of the set of \(y\in (0,l_{y})\) with \(u_{y}(x,y)=1-\theta \). We define
This equation is equivalent to \(u^{T}(x)=u^{B}(x)+(1-\theta ) M(x) -\theta (l_{y}-M(x))\).
The main idea is to move the interfaces in order to modify the volume of the minority phase by a factor \(\alpha (x)\), bringing it to the value required by the new boundary data,
Correspondingly the volume of the majority phase is modified by a factor \(\beta (x)\), so that the total length of \((0,l_{y})\) is unchanged, see Fig. 6. We define
From (81), \(c_{y}\ge 6 \hat{c}\) and \(l_{y} \geq c_{y} h_{0}\) we obtain \(|u^{B}(x)-u^{T}(x)|\le \frac{1}{3}\theta l_{y}\) and therefore
and \(l_{y}-M(x)\ge (1-\frac{4}{3}\theta )l_{y}\ge \frac{1}{3}l_{y}\ge \frac{2}{3} \theta l_{y}\). Similarly, with \(\hat{M}-M=v^{T}-u^{T}\),
so that in particular \(\alpha ,\beta \in [\frac{1}{2},2]\) a.e. Using (86) and \(c_{y}\ge 3\) we also obtain
Further, \(\alpha \in W^{1,2}((0,l_{x}))\) with
so that
Analogously, using \(l_{y}-M\ge \frac{1}{3} l_{y}\), we obtain
Using (85), (86), \(h_{0}\le l_{y}\) and (83), we obtain
for some \({\tilde{c}}>0\) depending only on \(\hat{c}\).
Step 2. Construction of a candidate \(v\) .
Fix any \(x\in (0,l_{x})\) such that \(u(x,\cdot )\) is Lipschitz continuous with \(u_{y}\in \{-\theta ,1-\theta \}\) a.e. We set
Then \(m(x,\cdot )\) is Lipschitz continuous with \(m_{y}\in \{0,1\}\) a.e., by Lemma 7, \(m\in C^{1/3}(R)\). The rescaling maps \([0,y]\) into \([0,F(x,y)]\), where
From \(m(x,l_{y})=M(x)\) we obtain \(F(x,l_{y})=l_{y}\), and from \(m_{y}\in \{0,1\}\) we obtain \(F_{y} =\alpha m_{y}+\beta (1-m_{y}) \in \{\alpha ,\beta \}\subset [ \frac{1}{2},2]\) a.e., so that \(F(x,\cdot )\) is a bilipschitz map from \([0,l_{y}]\) onto itself. Further, \(u \in W^{1,2}(R)\), (83) and (89) imply \(F\in W^{1,2}(R)\).
We aim to define \(v(x,y)\) such that \(v(x,0)=u^{B}(x)\), \(v_{y}(x,\cdot )=1-\theta \) on a subset of measure \(\alpha m\) of \([0, F(x,y)]\), and \(v_{y}(x,\cdot )=-\theta \) on the rest, which has measure \(\beta (y-m)\). This leads to the definition
which also satisfies \(v(x,l_{y})=v^{T}(x)\). Additionally, since \(v^{T}(0)=0 =u^{T}(0)\) we have \(\beta (0) = \alpha (0) =1\) and hence \(v(0,F(0,y))=u(0,y) =0\). By the same argument, if \(v^{T}(l_{x}) =u^{T}(l_{x})\) we have \(F(l_{x},y) =y\) and \(v(l_{x},y) = u(l_{x},y)\).
Step 3. Verify the desired properties of \(v\) .
Since \(F(x,\cdot )\) is bilipschitz, for almost every \(y\) we have
Recalling that (90) implies \(F_{y}=\alpha m_{y}+\beta (1-m_{y})\) and that \(m_{y}\in \{0,1\}\) almost everywhere, we obtain \(v_{y}\in \{-\theta ,1-\theta \}\). By the same reasoning we see that the number of jump points of \(v_{y}\) is the same as for \(u_{y}\), so that \(|v_{yy}|(R)=|u_{yy}|(R)\). Moreover, \(v_{y}(\cdot ,0) =u_{y}(\cdot ,0)\) and \(v_{y}(\cdot ,l_{y}) =u_{y}(\cdot ,l_{y})\) in the sense of traces.
It remains to estimate the derivative in \(x\). We first show that \(v\) is weakly differentiable. Let \(\Phi (x,y):=(x,F(x,y))\). Since \(F\in C^{0}(R)\) and \(F(x,\cdot )\) is bilipschitz from \([0,l_{y}]\) onto itself, \(\Phi \) is a continuous bijective map from \(R\) onto itself. The inverse \(\Psi \) obeys \(\Psi _{1}(x,y)=x\). Further, \(\Phi \in W^{1,2}(R;\mathbb{R}^{2})\), with \(\det D\Phi =F_{y}\in [\frac{1}{2},2]\) a.e., which implies \(\Psi \in W^{1,2}_{\mathrm{loc}}(R;\mathbb{R}^{2})\) (see [26, Th. 3.1]); by \(\Psi _{y}=(0,1/F_{y})\in L^{\infty }\) and Lemma 7\(\Psi \) is continuous. In order to prove that \(v\in W^{1,2}(R)\), we rewrite (91) as
We first show that \(m\circ \Psi \in W^{1,1}(R)\). This follows from general results on mappings of finite distortion, see [30, Th. 1.1], [35, Th. 1.3] or [31, Chap. 5]; for simplicity we give a self-contained argument. Let \(m^{\varepsilon }\in C^{1}_{c}(\mathbb{R}^{2})\) be such that \(m^{\varepsilon }\to m\) uniformly and strongly in \(W^{1,2}(R)\). Obviously \(m^{\varepsilon }\circ \Psi \to m\circ \Psi \) uniformly. Further, \(D(m^{\varepsilon }\circ \Psi )=Dm^{\varepsilon }\circ \Psi D\Psi \); with \(\det D\Psi \in [\frac{1}{2},2]\) and the change-of-variables formula we obtain \(Dm^{\varepsilon }\circ \Psi \to Dm\circ \Psi \) in \(L^{2}(R;\mathbb{R}^{2})\). As \(D\Psi \in L^{2}(R;\mathbb{R}^{2\times 2})\), by Hölder’s inequality \(D(m^{\varepsilon }\circ \Psi )\to Dm\circ \Psi D\Psi \) in \(L^{1}(R;\mathbb{R}^{2})\). By continuity of the distributional derivative we obtain \(D(m\circ \Psi )=Dm\circ \Psi D\Psi \in L^{1}(R;\mathbb{R}^{2})\).
Using \(m_{y}\in L^{\infty }(R)\), \(m_{x}\in L^{2}(R)\) and \(D\Psi _{1}=e_{1}\in L^{\infty }(R;\mathbb{R}^{2})\), we obtain \(Dm\circ \Psi D\Psi \in L^{2}(R;\mathbb{R}^{2})\), so that \(m\circ \Psi \in W^{1,2}(R;\mathbb{R}^{2})\). With \(\alpha \in W^{1,2}((0,l_{x}))\cap L^{\infty }((0,l_{x}))\), recalling \(m\in L^{\infty }(R)\) and using the product rule we obtain \(v\in W^{1,2}(R)\). This argument also proves that the chain rule applies in (91).
Differentiating (91) in \(x\), and dropping for brevity the arguments, we obtain
which, by \(u(x,y)=u^{B}(x)+m(x,y) - \theta y\), is the same as
or, using that by (90) \(F_{x} = (\alpha m)_{x} + (\beta ( y-m))_{x}\), the same as
Recalling that \(v_{y}\in \{-\theta ,1-\theta \}\) a.e. we then obtain \(v_{x}\in \{(\alpha m)_{x} -m_{x}+u_{x},(\beta (m- y))_{x} -m_{x}+u_{x} \}\) almost everywhere. Using \(0\le m\le M\) and (87), this leads to
in the first case, and, using \(0\leq y-m \leq l_{y}\), to
in the other case, so that with (88) we obtain that almost everywhere
By a change of variables,
By triangle inequality
which, using \(F_{y}\le 1+{\eta }^{1/2}\) (which follows from (88) and \(F_{y}\in \{\alpha , \beta \}\)) and (92), leads to the pointwise bound
By integration, together with (82), (83) and (89), we obtain
which, using again (82), leads to
Recalling that \({\tilde{c}}\) only depends on \(\hat{c}\), this concludes the proof. □
We then turn to asymptotic self-similarity. The first step is to find a subrectangle of \(R^{L_{x}, L_{y}}\) containing \((0, y_{0})\) on which the bounds of Theorem 3 hold. This is done using Theorem 4. In a second step we prove asymptotic self-similarity using the argument from [17, Sect. 3], which was extended to arbitrary \(\theta \in (0,1/2]\) in [43, Sect. 9].
Proof of Theorem 2
Let \(u \in \mathcal{A}_{0}(R^{L_{x}, L_{y}})\) be a minimizer of \(I(\cdot , R^{L_{x},L_{y}})\) and \(y_{0} \in (0, L_{y})\).
Step 1. We choose a subrectangle on which the local bounds of Theorem 3 hold.
We replace \(u\) by its continuous representative and let \(C_{H}\) be its Hölder constant (Lemma 7). For any \(l_{x}\in (0,L_{x}]\) and \(y\in [0,L_{y}]\) we have
In the following, we assume
which implies that \(|u|(l_{x},y)\le \frac{1}{2} \theta L_{y}\), so that we can apply Theorem 4. We obtain
Further, let \(\eta \in (0, \frac{1}{6})\) satisfy \(y_{0} \in (3\eta L_{y}, (1-3\eta )L_{y})\). Let \(c_{1}^{*}, c_{2}>0\) be the constants from Theorem 3 corresponding to our choice of \(\eta \) and \(k_{1}:=C\). We next show that we can choose \(c_{1}\ge c_{1}^{*}\) and \(l_{x}\in (0, l_{x}^{*}]\) such that (6) and (7) are satisfied; Condition (8) follows immediately from (93). For some \(c_{1}\) chosen below, we set
so that (6) is automatically satisfied. For \(c_{1}\) sufficiently large, in the sense that
both \(c_{1}\) and \(l_{x}\) are admissible.
It remains to choose \(c_{1}\) so that (95) and (7) hold. By (93) and Hölder’s inequality,
We fix some \(\alpha \in (0,1]\) chosen below, and apply Lemma 4 to \(u(l_{x},\cdot )\) with \(\delta := \alpha \eta L_{y}\). We obtain
By the definition of \(l_{x}\) we have \(c_{1}c_{2}\varepsilon ^{1/3} \theta ^{1/3} l_{x}^{2/3}= \frac{1}{2} c_{2} \eta L_{y}\theta \). Therefore
We set \(\alpha :=\min \{1,\frac{1}{4}c_{2}\}\), so that the first term is not larger than \(1/2\), and then choose \(c_{1}\) sufficiently large that (95) is satisfied and the second term is also not larger than \(1/2\). Therefore, Theorem 3 can be applied to the rectangle \((0,l_{x})\times (0, L_{y})\).
Step 2. We prove the asymptotic self similarity.
We follow the lines of [17, Sect. 3], where one has to substitute \(R^{L_{x}, L_{y}}\) with
in which (9) and (10) hold. We define \(u^{j}(x,y) = \nu _{j}^{-2/3} u(\nu _{j} x, y_{0} +\nu _{j}^{2/3}y)\) as in (3) and observe that \(u^{j} \in \mathcal{A}_{0}(R_{*}^{j})\), where
Clearly \(\bigcup _{j\in \mathbb{N}} R^{j}_{*}= (0, \infty ) \times \mathbb{R}\). Further, the estimates of Theorem 3 remain true for \(u^{j}\) on \(R_{*}^{j}\). Indeed,
for \((x,y) \in R_{*}^{j}\) and, by a change of variables,
for \(b-a \ge 4c_{1} \varepsilon ^{1/3}\theta ^{-2/3}l^{2/3}\), provided \(j\in \mathbb{N}\) is sufficiently large that \((0,l)\times (a,b) \subseteq R_{*}^{j}\). In particular, in each such rectangle there is a subsequence which converges weakly in \(W^{1,2}\). Taking a diagonal subsequence, still denoted by \((u^{j})_{j}\), we see that there exists \(u^{\infty }\in W^{1,2}_{\mathrm{loc}}((0, \infty )\times \mathbb{R})\) with
-
(i)
\(u^{j} \rightharpoonup u^{\infty }\) weakly in \(W^{1,2}_{\mathrm{loc}}((0, \infty ) \times \mathbb{R})\),
-
(ii)
\(u^{j}_{yy} \rightharpoonup u^{\infty }_{yy}\) weakly as Radon measures on \((0, \infty ) \times \mathbb{R}\),
-
(iii)
\(u^{j} \rightarrow u^{\infty }\) uniformly in every compact set \(K \subseteq [0, \infty ) \times \mathbb{R}\)
as \(j \rightarrow \infty \). The last convergence follows from Lemma 7 and the compact embedding \(C^{1/3}({K}) \hookrightarrow ^{c} C^{0}({K})\) for any compact subset \(K \subseteq [0, \infty ) \times \mathbb{R}\). These conditions in particular imply that \(u^{\infty }(0,\cdot )=0\) and \(u^{\infty }_{yy}\) is a Radon measure. From (i) and (ii) we obtain, using compensated compactness [48, 54], that \(u^{j}_{y} \rightarrow u^{\infty }_{y}\) strongly in \(L^{2}_{\mathrm{loc}}((0, \infty ) \times \mathbb{R})\) (see [41, Lemma 2.2] for a self-contained argument). Therefore \(u^{\infty }\in \mathcal{A}_{0}((0,l)\times (a,b))\) for all \(l>0\) and \(a< b\). By lower semicontinuity of the various norms involved, (96) and (97) hold also for \(u^{\infty }\).
We next prove the existence of a subsequence \((u^{j})_{j}\) such that \((u_{x}^{j})_{j}\) converges strongly in \(L^{2}_{\mathrm{loc}}([0, \infty )\times \mathbb{R})\) towards \(u^{\infty }_{x}\), which means that it converges strongly in \(L^{2}(R_{l,h})\) for all \(l,h>0\), where we write \(R_{l,h}:=(0,l)\times (-h,h)\). We shall show below that there is \(\bar{c}>0\) such that for any \(l_{x}>0\) and \(H\ge \bar{c} \varepsilon ^{1/3}\theta ^{-2/3}l_{x}^{2/3}\),
Fix \(l_{x}>0\), \(h>0\). For \(H\) sufficiently large, using twice (98) we obtain
where \(C:=c\varepsilon ^{2/3}l_{x}^{5/6}\theta ^{-1/3}\) is independent of \(H\). By (97), we get
for \(H\) large. Taking \(H\to \infty \) shows that \(\limsup _{j\to \infty } \|u_{x}^{j}-u_{x}^{\infty }\|^{2}_{L^{2}(R_{l_{x},h})}=0\) which, since \(l_{x}\) and \(h\) were arbitrary, concludes the proof of strong convergence.
Step 3. Proof of (98).
The idea is to relate the \(L^{2}\) norm of the difference to the difference in energy via
where the integral of the last term converges to zero by weak convergence. We fix \(H \geq \bar{c} \varepsilon ^{1/3}\theta ^{-2/3}l_{x}^{2/3}\), recall the notation \(R_{l,h}=(0,l)\times (-h,h)\) and define \(f_{j}:(0,H)\to \mathbb{R}\) by
The first integral converges to zero for any \(h\in (0, H)\). By lower semi-continuity, \(|u^{\infty }_{yy}|(R_{l_{x},h})\le \liminf |u^{j}_{yy}|(R_{l_{x},h})\) for all \(h\in (0, H)\). Therefore \(f_{j}(h)\to 0\) pointwise. By Egorov’s theorem there is \(A_{f}\subset (0,H)\) with
To estimate the differences in energy we will construct a competitor \(w^{j}\) that coincides with \(u^{\infty }\) on some inner rectangle and is larger in energy than \(u^{j}\) on a larger rectangle. We set
By (iii) we have \(s_{j}\to 0\); for large \(j\) we can assume \(s_{j}<1\). Let \(\ell _{j}:=s_{j} l_{x}\in (0, l_{x})\). We define \(\tilde{u}^{j}:R_{2l_{x},H}\to \mathbb{R}\) by
We verify that \(\tilde{u}^{j}=u^{j}\) for \(x\ge {l_{x}}+\ell _{j}\), \(\tilde{u}_{y}^{j}\in \{u_{y}^{j},u^{\infty }_{y}\}\subseteq \{-\theta ,1- \theta \}\), \(|\tilde{u}^{j}|\le \max \{|u^{j}|,|u^{\infty }|\}\), and \(\tilde{u}_{x}^{j}\in \{u_{x}^{\infty }+\frac{s_{j}}{\ell _{j}}, u_{x}^{\infty }-\frac{s_{j}}{\ell _{j}}, u^{\infty }_{x},u_{x}^{j}\}\) almost everywhere, which implies
To estimate \(|\tilde{u}^{j}_{yy}|\) we use the following fact. If \(f,g:(a,b)\to \mathbb{R}\) are continuous and piecewise affine, with \(f',g'\in \{-\theta ,1-\theta \}\), then \(h:=\min \{f,g\}\) obeys \(\# Jh'\le 1 +\#Jf'+\#Jg'\), where \(Jf'\) is the set of discontinuity points of \(f'\) and \(\#Jf'\) its cardinality, which equals the total variation of the measure \(|f''|\) over \((a,b)\). We first prove this if \(\{f=g\}\) is a finite set. By definition of \(h\), \(Jh'\subseteq Jf'\cup Jg'\cup \{f=g\}\) (see Fig. 7). If \(\#\{f=g\}\leq 1\), the claim follows. Otherwise, let \(x< y\) be two consecutive points in \(\{f=g\}\). Assume that \(f< g\) in \((x,y)\). Then necessarily \((x,y)\cap Jg'\ne \emptyset \), and this point does not contribute to \(Jh'\). Therefore \(\#\{f=g\}\) is at most one plus the number of points in \(Jf'\) and \(Jg'\) which do not generate a point in \(Jh'\). This proves \(\# Jh'\le 1 +\#Jf'+\#Jg'\) if \(\{f=g\}\) is finite. Otherwise we consider \(h_{\delta }:=\min \{f,g+\delta \}\), send \(\delta \to 0\), and use lower semicontinuity of \(\#Jh_{\delta }'\).
Therefore \(|\tilde{u}^{j}_{yy}|((l_{x}, l_{x}+\ell _{j})\times (a,b))\le |u^{j}_{yy}|((l_{x}, l_{x}+\ell _{j})\times (a,b))+ |u^{\infty }_{yy}|((l_{x}, l_{x}+\ell _{j}) \times (a,b))+\varepsilon l_{x}\). Further, \(\tilde{u}^{j}\in \mathcal{A}_{0}(R_{2l_{x},H})\), and for any \((a,b)\subseteq (-H,H)\) we obtain
where, recalling (102), the choice of \(\ell _{j}\) and \(s_{j}\to 0\),
Next we intend to use Lemma 8 with \(\hat{c}:=\max \{ 32d_{2}, {2}d_{1}\}\). Let \(c_{y}\) be the corresponding constant and \(h:={\max \{c_{y},8c_{1}\}}h_{0}\). We fix \(\bar{c}\) so that \({H}\ge 2h\) and then select \({h_{j}}\in (\frac{1}{2} {H}, {H})\) which satisfies several properties. First, for almost all \(h_{j}\) we have \(|u^{j}_{yy}|((0,2l_{x})\times \{h_{j}\})= |u^{\infty }_{yy}|((0,2l_{x}) \times \{h_{j}\})=0\), the same for \(-h_{j}\), and for at least three quarters of the \(h_{j}\)
Second, using (97) on \((0,2l_{x})\times (-{H},{H})\), for at least three quarters of the \(h_{j}\) we have
Third, for three quarters of the \(h_{j}\)
Finally, since \(\mathcal{L}^{1}(A_{f})\le \frac{1}{12}H\), we can choose a value of \(h_{j}\in (\frac{1}{2}H,H)\setminus A_{f}\) which obeys all those properties.
We check that we can apply Lemma 8 on \((0,{l_{x}}+\ell _{j})\times ({h_{j}}-h, {h_{j}})\) with \(u=\tilde{u}^{j}\), \(v^{T}=u^{{j}}(\cdot , {h_{j}})\). Indeed, from the definition of \(\tilde{u}^{j}\) we have \(|\tilde{u}^{j}|\le \max \{|u^{j}|,|u^{\infty }|\}\), so that (96) and \({2}d_{1}\le \hat{c}\) imply (81). In turn, (102) and (97) with \((a,b)=({h_{j}}-h, {h_{j}})\) show that
so that, recalling \(8d_{2}\le \hat{c}\), for sufficiently large \(j\) (82) holds. Finally, (106) and \(32d_{2}\le \hat{c}\) imply (83). From \(|u^{j}_{x}- \tilde{u}_{x}^{j}|\leq |u^{j}_{x}-u^{\infty }_{x}| + s_{j}/ \ell _{j} \chi _{(l_{x}, l_{x}+\ell _{j})\times \mathbb{R}}\) and (107) we obtain
By (97), \(\eta _{j}\le 42d_{2}\) for large \(j\). Lemma 8 gives a function \(w^{j,T}\) with
where \(C_{I}\) depends on \(c_{I}\), \(d_{2}\), \(c_{y}\) and \(c_{1}\). We apply the same procedure on the other side using again \(u=\tilde{u}^{j}\), \(v^{B}=u^{{j}}(\cdot ,-h_{j})\) and obtain \(w^{j,B}\) on \((0,{l_{x}}+\ell _{j})\times ({-h_{j}}, {-h_{j}}+h)\). We set
see Fig. 8. By the boundary values given by Lemma 8, \(w^{j}\in \mathcal{A}_{0}(R_{2l_{x},H})\). Since \(u^{j}\) is a local minimizer, \(I(u^{j},R_{2l_{x},H})\le I(w^{j},R_{2l_{x},H})\). Using \(u^{j}=w^{j}\) outside \((0,l_{x}+\ell _{j})\times (-h_{j},h_{j})\), recalling (105) and \(w^{j}_{y}(\cdot ,\pm h_{j})=u^{j}_{y}(\cdot ,\pm h_{j})\), we have
where in the last step we used (103). Therefore
Using \(h_{j}\ge \frac{1}{2} H\) and (99), this implies
Equation (100) implies \(f_{j}(h_{j})\to 0\), and (104) implies \(\omega _{j}\to 0\). By (105) and strong convergence of \(u_{y}^{j}\) we have \(r^{j}({h_{j}})\to 0\). In turn, (107) gives
Combining the last two inequalities concludes the proof of (98) and of strong convergence.
Step 4. Proof that \(u^{\infty }\) is a local minimizer.
Assume that \(\hat{u}^{\infty }\in \mathcal{A}_{0}((0,\infty )\times \mathbb{R})\) is such that \(\{u^{\infty }\ne \hat{u}^{\infty }\} \subset K\) for some compact set \(K\subset [0,\infty )\times \mathbb{R}\). Pick \(l_{x}\) and \(H\) such that \(K\subset (0,l_{x})\times (-H/2,H/2)\), with \(H\) sufficiently large such that the computation of Step 3 can be performed. We remark that the function \(w^{j}\) coincides with \(u^{\infty }\) in \((0,l_{x})\times (-h_{j},h_{j})\). Therefore \(\hat{w}_{j}:= w_{j}+ (\hat{u}^{\infty }-u^{\infty })\in \mathcal{A}_{0}((0, \infty )\times \mathbb{R})\), and it coincides with \(u^{j}\) outside \((0,l_{x}+\ell _{j})\times (-h_{j},h_{j})\). By the same estimate that lead to (110),
By (99),
Recalling \(\{u^{\infty }\ne \hat{u}^{\infty }\}\subseteq (0,l_{x})\times (-H/2,H/2)\) and \(h_{j}>H/2\), this leads to
and, taking the limit \(j\to \infty \) and using strong convergence to obtain \(\eta _{j}\to 0\),
Therefore \(u^{\infty }\) is a local minimizer. □
We next show convergence of the energy on most rectangles. This argument is similar to the one of [17, 43], where however the choice of \(a\) and \(b\) is imprecise.
Lemma 9
Under the assumptions of Theorem 2, the subsequence additionally obeys
for almost all \(a,b \in \mathbb{R}\) with \(a< b\).
Proof
The following is based on the estimates and observations of Step 3 in the proof of Theorem 2.
Fix \(l_{x}>0\). We introduce the set of admissible boundary lines
We have \(\vert u_{yy}^{\infty }\vert ((0, l_{x})\times (-n , n)) < \infty \) for any \(n \in \mathbb{N}\) due to the weak lower semi-continuity of the total variation and (97). Thus, there can only be countably many \(h \in (-n, n) \) with \(\vert u_{yy}^{\infty }\vert ((0, l_{x})\times \{h\}) > 0\). Hence, \(\mathbb{R}\setminus \mathcal{P}\) is a countable set.
Let \(R^{l_{x}, a, b} \coloneqq (0, l_{x}) \times (a,b) \subseteq (0, \infty )\times \mathbb{R}\) with \(a, b\in \mathcal{P}\) and \(H \geq 2\max \{ \vert a\vert , \vert b \vert \}\). Observe, that the weak lower semi-continuity of the total variation and the strong convergence proven in Theorem 2 yield
Hence, we only need to prove
Similar to (100) we aim at an application of Egorov’s Theorem. Therefore, we introduce the functions \(g_{j} \colon ( \frac{1}{2} H, H) \rightarrow \mathbb{R}\) via the formula
for \(h \in (\frac{1}{2} H, H)\) and \(j\in \mathbb{N}\). The weak lower-semicontinuity of the total variation and the choice \(a,b \in \mathcal{P}\) imply
which implies \(\limsup _{j \rightarrow \infty } g_{j}(h) \leq 0\) for almost every \(h \in (\frac{1}{2} H, H)\). Hence, the sequence \((\max \{ g_{j}, 0\})_{j}\) converges pointwise almost everywhere towards zero. By Egorov’s Theorem there exists a measurable set \(A_{g} \subseteq (\frac{1}{2} H, H)\) with
Using \(A_{f}\) from (100) we choose \(\tilde{h}_{j} \in (\frac{1}{2} H, H) \setminus (A_{g}\cup A_{f})\) such that all the properties (105), (106) and (107) are satisfied. Observe
where we have used the estimate (110). Together with (111) and (113) this yields
which implies the desired convergence. □
8 Remarks on the Periodic Problem
In this section, we briefly discuss how the results of the preceding sections can be transferred to the periodic case, i.e. to the set of admissible functions which are periodic in \(y\)-direction,
On \(\mathcal{A}_{P}(R^{L_{x}, L_{y}})\) we consider both, the functional \(I(\cdot , R^{L_{x}, L_{y}})\) and a variant which takes into account interfaces of the \(L_{y}\)-periodic extension of \(u\) on \((0,L_{x})\times \{L_{y}\}\). Precisely, denoting by \(Eu:(0,L_{x})\times \mathbb{R}\to \mathbb{R}\) the \(L_{y}\)-periodic extension of \(u\), and writing \(u_{y}^{+}(\cdot ,0)\) and \(u_{y}^{-}(\cdot ,L_{y})\) for the upper and lower traces, respectively, we set
Remark 5
Let \(u\in \mathcal{A}_{P}(R^{L_{x}, L_{y}}) {\subseteq \mathcal{A}_{0}(R^{L_{x}, L_{y}})}\). Then the following assertions hold:
-
(i)
For almost every \(x\in (0,L_{x})\), we have
$$ \begin{aligned} 0&=u(x,L_{y})-u(x,0)=\int _{0}^{L_{y}}u_{y}(x,y)\,\, \mathrm{d}y \\ &=-\theta \left |\{y:u_{y}(x,y)=-\theta \}\right | +(1-\theta )\left | \{y:u_{y}(x,y)=1-\theta \}\right |, \end{aligned} $$which implies that the volume fraction of the minority variant \(\{u_{y}(x,\cdot )=1-\theta \}\) on the slice \(\{x\}\times (0,L_{y})\) is equal to \(\theta \). Recalling \(0<\theta \leq 1/2<1\), we obtain
$$\begin{aligned} &|u_{yy}(x,\cdot )|((0,L_{y}))= |Eu_{yy}|(x,\cdot )|((0,L_{y}))\geq 1, \quad \text{and} \end{aligned}$$(114)$$\begin{aligned} &\vert Eu_{yy}(x,\cdot )\vert ((0,L_{y}))+1 \geq \vert Eu_{yy}\vert (x, \cdot )((0,L_{y}])\geq 2. \end{aligned}$$(115)In particular,
$$\begin{aligned} I(u, R^{L_{x}, L_{y}}) \le I_{P}(u, R^{L_{x}, L_{y}})\leq I(u, R^{L_{x}, L_{y}})+ \varepsilon L_{x}. \end{aligned}$$(116) -
(ii)
For all \(a\in \mathbb{R}\) we have
$$ I_{P}(u, R^{L_{x}, L_{y}})= I_{P}(Eu, (0,L_{x})\times (a,a+L_{y})). $$ -
(iii)
If \(u\) is a minimizer of \(I(\cdot , R^{L_{x}, L_{y}})\) then its restriction is a local minimizer in the sense of (11) on any subrectangle \(R^{l_{x},a,b}=(0,l_{x})\times (a,b)\subseteq R^{L_{x}, L_{y}}\).
-
(iv)
If \(u\) is a minimizer of \(I_{P}(\cdot ,R^{L_{x},L_{y}})\) then \(u\) is also a local minimizer of \(I(\cdot ,R^{L_{x},L_{y}})\). Also, for any subrectangle \(R^{l_{x},a,b}\subseteq (0,\infty )\times \mathbb{R}\) with \(b-a\leq L_{y}\)
$$\begin{aligned} I_{P}(Eu, R^{l_{x}, a, b}) \le I_{P}(v, R^{l_{x}, a, b}) \text{ for all } v\in \mathcal{A}_{0}(R^{l_{x}, a, b}) \text{ such that there } \\ \text{exists $\delta >0$ with } \{v \ne u\}\subset (0,l_{x}-\delta ) \times (a +\delta ,b-\delta ). \end{aligned}$$(117)
Theorem 5
Global scaling laws
There is \(c_{P}>0\) such that for all \(\varepsilon \), \(L_{x}\), \(L_{y}>0\) and \(\theta \in (0,\frac{1}{2}]\) one has
Proof
This is also a special case of [19, Theorem 1.2]. Observe that (116) implies the second inequality. The first inequality (lower bound) follows from the fact that \(\vert u_{yy}\vert (R^{L_{x}, L_{y}})\ge \varepsilon L_{x}\) holds for any function \(u \in \mathcal{A}_{P}(R^{L_{x}, L_{y}})\subseteq \mathcal{A}_{0} (R^{L_{x}, L_{y}})\) and the lower bound in Theorem 1.
For the third inequality (upper bound), we consider the two cases separately. If \(L_{x} \le l_{x} \coloneqq \varepsilon ^{-1/2}\theta L_{y}^{3/2}\) then \(\varepsilon L_{x}\leq \varepsilon ^{2/3}\theta ^{2/3}L_{x}^{1/3}L_{y}\) and the respective construction from the proof of Theorem 1 is an admissible function. If \(L_{x} \ge l_{x}\), we set
on \([l_{x}, L_{x})\times [0, L_{y})\), and use Proposition 1 in \((0, l_{x})\times (0,L_{y})\) with \(u^{L}=0\), \(u^{B}=u^{T}=0\), \(u^{R}(y)=u(l_{x},y)\), see Fig. 9.
□
Theorem 6
Local bound
Let \(u \in \mathcal{A}_{P}(R^{L_{x}, L_{y}})\) be a minimizer of \(I(\cdot , R^{L_{x}, L_{y}})\) and \(u^{P} \in \mathcal{A}_{P}(R^{L_{x}, L_{y}})\) a minimizer of \(I_{P}(\cdot , R^{L_{x}, L_{y}})\). Furthermore, let \(l_{x} \in (0, \min \{ \varepsilon ^{-1/2}\theta L_{y}^{3/2}, L_{x}\})\). There are constants \(C_{P}, C_{P}^{\prime }> 0\), independent of \(l_{x}, L_{x}, L_{y}, \varepsilon \) and \(\theta \), such that
and
Proof
The lower bounds follow from Theorem 5. To prove the upper bounds, we proceed along the lines of the proof of Theorem 4. As in Lemma 3 there exists a constant \(\tau _{P} \in \mathbb{R}\) and a density \(\sigma _{P} \in L^{2}((0, L_{x}))\) such that
hold, where \(c_{P} > 0 \) is the constant introduced in Theorem 5. We then construct a competitor \(v \in \mathcal{A}_{P}(R^{l_{x}, L_{y}})\) using Proposition 1. Note that in view of Lemma 7, we may assume that \(u\) is continuous, and thus by Remark 5, \(u^{T}(l_{x},0)=u^{B}(l_{x},L_{y})\). Therefore, setting \(u^{T}:=u^{T,l}\) and \(u^{B}:=u^{B,l}\), the assumption (28) is satisfied, and we obtain a competitor in \(\mathcal{A}_{P}\) which allows us to conclude the proof of (118) along the lines of the proof of Theorem 4. Finally, the upper bound in (119) follows analogously using (116). □
Remark 6
By the arguments given in [27, Sect. 4] (cf. the first part of the proof of Lemma 2), we have the following property for the continuous representatives of minimizers \(u\) (respectively \(u^{P}\)) of \(I\) (respectively \(I_{P}\)): If \(|u_{yy}(\bar{x},\cdot )|((0,L_{y}))=\min \{|u_{yy}(x,\cdot )|(0,L_{y}):x \in (0,L_{x})\}\) then \(u(x,y)=u(\bar{x},y)\) for all \(x\in [\bar{x},L_{x})\). Similarly, if \(|u^{P}_{yy}(\bar{x},\cdot )|((0,L_{y}])=\min \{|u^{P}_{yy}(x,\cdot )|(0,L_{y}]:x \in (0,L_{x})\}\) then \(u^{P}(x,y)=u^{P}(\bar{x},y)\) for all \(x\in [\bar{x},L_{x})\). Proceeding as in the proof of Lemma 2, using (114) and (115) we obtain the following (quantitative) results with the constant \(c_{P} > 0\) from Theorem 5:
-
(i)
If \(L_{x} \ge l_{x} \coloneqq \frac{c_{P}}{2} \varepsilon ^{-1/2}\theta L_{y}^{3/2}\) and \(u\in \mathcal{A}_{P}(R^{L_{x}, L_{y}})\) is a minimizer of \(I(\cdot , R^{L_{x}, L_{y}})\) then \(u(x,y)=u(l_{x},y)\) and \(\vert u_{yy}(x, \cdot )\vert ((0, L_{y})) = 1\) hold for \(x\in [l_{x},L_{x})\).
-
(ii)
If \(L_{x} \ge l^{P}_{x} \geq \frac{c_{P}}{3} \varepsilon ^{-1/2}\theta L_{y}^{3/2}\) and \(u^{P}\in \mathcal{A}_{P}(R^{L_{x}, L_{y}})\) is a minimizer of \(I_{P}(\cdot , R^{L_{x}, L_{y}})\) then \(u^{P}(x,y)=u^{P}(l_{x}^{P},y)\) and \(\vert Eu^{P}_{yy}(x, \cdot )\vert ((0, L_{y}]) = 2\) hold for \(x\in [l_{x}^{P},L_{x})\).
The asymptotic self-similarity of a minimizer of \(I(\cdot , R^{L_{x}, L_{y}})\) or \(I_{P}(\cdot , R^{L_{x}, L_{y}})\) on \(\mathcal{A}_{P}(R^{L_{x}, L_{y}})\) can be shown in the same way as in the Neumann case (Theorem 2), using Remark 5.
Theorem 7
Asymptotic self-similarity of a minimizer
Let \(\varepsilon , L_{x}, L_{y}>0\) and \(\theta \in (0,\frac{1}{2}]\), and fix any sequence \(\nu _{j}\to 0\), \(\nu _{j}>0\). Then, the following two results hold:
-
(i)
Let \(u \in \mathcal{A}_{P}(R^{L_{x}, L_{y}})\) be a minimizer of \(I(\cdot ,R^{L_{x},L_{y}})\) and \(y_{0}\in (0, L_{y})\). Then the sequence \(u^{j}(x,y) \coloneqq \nu _{j}^{-2/3}{Eu}(\nu _{j} x, y_{0} + \nu _{j}^{2/3}y)\) has a subsequence that converges strongly in \(W^{1,2}_{\mathrm{loc}}((0,\infty )\times \mathbb{R})\) towards an element \(u^{\infty }\in \mathcal{A}_{0}((0,\infty )\times \mathbb{R})\), and \(u^{\infty }\) is a local minimizer.
-
(ii)
Let \(u_{P} \in \mathcal{A}_{P}(R^{L_{x}, L_{y}})\) be a minimizer of \(I_{P}(\cdot , R^{L_{x}, L_{y}})\) and \(y_{0}\in [0, L_{y}]\). Then the sequence \(u_{P}^{j}(x,y) \coloneqq \nu _{j}^{-2/3}{Eu}_{P}(\nu _{j} x, y_{0} + \nu _{j}^{2/3}y)\) has a subsequence that converges strongly in \(W^{1,2}_{\mathrm{loc}}((0,\infty )\times \mathbb{R})\) towards an element \(u^{\infty }_{P} \in \mathcal{A}_{0}((0,\infty )\times \mathbb{R})\), and \(u^{\infty }_{P}\) is a local minimizer.
Both \(Eu\) and \(Eu_{P}\) are implicitly extended by zero to the rest of \((0,\infty )\times \mathbb{R}\).
Remark 7
We point out that we obtain the asymptotic self-similarity of minimizers of \(I_{P}(\cdot , R^{L_{x}, L_{y}})\) also for the boundary points \(y_{0}\in \{0, L_{y}\}\).
Proof
Both assertions can be derived following the proof of Theorem 2, where the first step can be omitted due to periodicity.
To prove that assertion (ii) holds also for the boundary points \(\{0,L_{y}\}\), we use Remark 5 (ii) and (iv). Precisely, for given \(y_{0}\in [0,L_{y}]\), we replace \(R^{L_{x}, L_{y}}\) with \((0, L_{x}) \times (y_{0} - L_{y}/2, y_{0} + L_{y}/2)\), choose \(\eta = \frac{1}{12}\) and proceed as in the proof of Theorem 2. □
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Acknowledgements
We are grateful to Peter Bella and Michael Goldman for interesting discussions, and in particular to Stefan Müller for his continuous support, and for, in different moments, bringing this problem to our attention. This work was partially funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) via projects 211504053 - SFB 1060 and 195170736 - TRR 109, and under Germany’s Excellence Strategy – The Berlin Mathematics Research Center MATH+ and the Berlin Mathematical School (BMS) (EXC-2046/1, project 390685689).
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Conti, S., Diermeier, J., Koser, M. et al. Asymptotic Self-Similarity of Minimizers and Local Bounds in a Model of Shape-Memory Alloys. J Elast 147, 149–200 (2021). https://doi.org/10.1007/s10659-021-09862-4
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DOI: https://doi.org/10.1007/s10659-021-09862-4
Keywords
- Calculus of variations
- Martensitic phase transformation
- Microstructure
- Asymptotic self-similarity
- Local bounds