Abstract
Well-posedness is proved for the stochastic viscous Cahn–Hilliard equation with homogeneous Neumann boundary conditions and Wiener multiplicative noise. The double-well potential is allowed to have any growth at infinity (in particular, also super-polynomial) provided that it is everywhere defined on the real line. A vanishing viscosity argument is carried out and the convergence of the solutions to the ones of the pure Cahn–Hilliard equation is shown. Some refined regularity results are also deduced for both the viscous and the non-viscous case.
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1 Introduction
The deterministic Cahn–Hilliard equation was first proposed in [6] to describe the spinodal decomposition phenomenon occurring during the phase separation in a binary metallic alloy. In order to model the dynamics of viscous phase-transitions, Novik–Cohen introduced in [56] the viscous regularization of the equation (see also [28, 29]).
The pure and viscous Cahn–Hilliard equations can be written in a unified form as
where D is a smooth bounded domain in \(\mathbb {R}^N\) (\(N=2,3\)), \(T>0\) is a fixed finite time, \(\Delta \) is the Laplace operator, g is a prescribed source term and \(\varepsilon \) is a nonnegative parameter: the case \(\varepsilon =0\) corresponds to the pure case, while \(\varepsilon >0\) corresponds to the viscous case. The unknowns of the equation are the order parameter u and the chemical potential \({\bar{w}}\). As usual, \(\beta \) is a maximal monotone operator and \(\pi \) is a Lipschitz-continuous function on \(\mathbb {R}\), so that the term \(\beta +\pi \) can be interpreted as the (sub)differential of a so-called double-well potential. This can be seen as a sum \({\widehat{\beta }}+{\widehat{\pi }}\), where \({\widehat{\beta }}\) is the convex part and \({\widehat{\pi }}\) the concave perturbation: in this setting, we have \(\beta =\partial {\widehat{\beta }}\) and \(\pi ={\widehat{\pi }}'\). We refer to [14] for some concrete example of double-well potentials. Usually, the equation is complemented with homogeneous Neumann boundary conditions for both u and \({\bar{w}}\), ensuring thus the conservation of the mean of u on D (as it follows directly integrating the first equation), and a given initial datum:
where \(\mathbf{n}\) stands for the outward normal unit vector on \(\partial D\).
In the last decades, the mathematical literature on deterministic Cahn–Hilliard equations has been widely developed. Existence of solutions, continuous dependence on the data and regularity have been studied for example in [7,8,9,10,11, 14, 37] also under refined frameworks such as the dynamic boundary conditions for u or \({\bar{w}}\). Asymptotic behaviour of the solutions have also been analyzed in [12, 13, 38]. More recently, some existence and uniqueness have been obtained when the dependence of \({\bar{w}}\) on the viscosity term is of nonlinear type: we mention in this direction the works [4, 55, 63]. Alongside the analysis of well-posedness for the equation, several results have also been achieved in the context of optimal control problems: we point out for example the contributions [15, 18, 19, 44].
It is well-known, however, that the deterministic model fails in taking into account the effects due to the random microscopic movements, which be of configurational, vibrational, electronic and magnetic type (see for example [21]). In order to capture the randomness of the phenomenon in the model, the most natural way is to add a cylindrical Wiener process in the first equation (see [48]), and obtain a stochastic partial differential equation in u. While the stochastic formulation of the problem is straightforward for the pure Cahn–Hilliard equation, due to the viscosity term we have to rearrange the system in a different way. To this end, note that if we formally substitute the second equation in the first one, the system can be written as
with Neumann boundary conditions for u and w. Consequently, the stochastic formulation of the system is given by
where W is a cylindrical Wiener process on a certain Hilbert space U and B is a suitable operator integrable with respect to W.
The main motivation behind the mathematical analysis of stochastic Cahn–Hilliard equations is to provide a theoretical starting point to study further models with stochastic perturbations which are relevant in terms of applications. Among all, in the last years there has been a growing interest in the study of phase field models for tumor growth, for example, which aim at describing the evolution of a tumoral mass within a healthy tissue according to several factors such as proliferation, apoptosis, nutrient consumption, etc. Such models usually couple a Cahn–Hilliard equation for the tumoral fraction with a reaction-diffusion equation for the nutrient: see for example [23, 35, 42, 43, 57] for the model derivation and [16, 17, 20, 32,33,34, 36] (and the references therein) for studies on well-posedness and optimal control. While in the deterministic setting such models have received much attention, we are not aware of any contribution dealing also with possible stochastic perturbations. In particular, any mathematical analysis of the stochastic counterpart would require first some solid well-posedness and regularity results for the stochastic Cahn–Hilliard equation itself, which is currently not very developed in literature. In this direction, this paper provides a starting point in terms of well-posedness and regularity for possible future studies of stochastic models involving Cahn–Hilliard equations. A joint work with C. Orrieri and E. Rocca on a stochastic version of a phase-field model for tumor growth is in preparation.
From the mathematical perspective, the stochastic Cahn–Hilliard has been studied so far mainly in the pure case \(\varepsilon =0\). Existence, uniqueness and regularity have been investigated in the works [22, 24, 27] for the stochastic pure Cahn-Hilliard equation with a polynomial double-well potential, and in [25, 39, 62] for the pure case with a possibly singular double-well potential. The reader can also refer to [1] for a study of a stochastic Cahn-Hilliard equation with unbounded noise and [25, 26, 39] dealing with stochastic Cahn–Hilliard equations with reflections. To the best of our knowledge, the only available results dealing with the stochastic viscous Cahn–Hilliard equation seem to be [41, 45]: here, the authors prove existence of mild solution and attractors under the classical case of a polynomial double-well potential. Let us also mention, for completeness, the contributions [3] dealing with a stochastic Allen-Cahn equation with constraints, and [30, 31] for a study of a diffuse interface model with termal fluctuations.
The aim and novelty of this paper is to carry out a unifying and self-contained mathematical analysis of the stochastic viscous Cahn–Hilliard system, under no growth nor smoothness assumptions on the double-well potential. This is motivated by the fact that, in applications to phase-transitions, degenerate potentials (possibly defined on bounded domains) play an important role (see again [14]): consequently, from the mathematical point of view, it is worth trying to give sense to the equation with as less constraints as possible on the growth of \(\beta \). In this direction, our previous contribution [62] analyzed the pure case with no growth restriction on the potential. A corresponding analysis for the viscous case is not available yet, and is performed here. More specifically, we prove well-posedness for the viscous equation under no growth nor smoothness conditions on \(\beta \). The only requirement is that \(\beta \) is everywhere defined on the real line: while this hypothesis is not needed in the deterministic theory, it seems to be essential in the stochastic case. Nevertheless, any order of growth for \(\beta \) at infinity (even super-exponential for example) is included in our treatment. The techniques that we use are based on a generalized variational approach, which has been also employed in order to analyse singular semilinear equations (see [49, 50, 54]), divergence-form equations (see [51,52,53, 61]), Allen-Cahn equations with dynamic boundary conditions (see [58]) and porous media equations (see [2]). The second main novelty of this paper is that we prove the convergence of solutions to the viscous Cahn–Hilliard equation to the ones of the pure equation, as the viscosity coefficient goes to 0. Such a convergence result is very relevant for many applications: indeed, the solutions to the viscous Cahn–Hilliard equation are much more regular and easier to handle, hence the possibility of approximating the (less regular) solutions to the pure equation can be used in practice for example in regularity problems. As an direct application of the vanishing viscosity limit, we prove some refined regularity results for the both the viscous and the pure case.
We are thus interested in studying the stochastic viscous Cahn–Hilliard equation with homogeneous Neumann boundary conditions in the following form:
Let us briefly summarize the contents of the work. Section 2 contains the main hypotheses of the paper and the statement of the main results: the well-posedness of the system with both additive and multiplicative noise, the vanishing viscosity limit and the regularity results. Section 3 deals with the proof of well-posedness. The main idea is to start considering the problem with additive noise, where \(\beta \) and B are regularized considering the Yosida approximation and an elliptic-type approximation in space, respectively. This is solved using the classical variational approach in a Hilbert triple, with a suitable dualization chosen ad hoc. Then uniform estimates on the approximated solutions, both pathwise and in expectation, together with compactness and monotonicity arguments, provide existence of solutions to the original problem. In particular, a crucial point is to prove a generalized Itô’s formula on a certain dual space, from which a very natural continuous dependence on the initial datum follows. The generalization to the case of multiplicative noise is carried out combining a Lipschitz-type assumption on B and a fixed point argument, and using a classical patching argument in time. In Sect. 4 we prove the asymptotic behaviour of the solutions as the viscosity coefficient goes to 0. Again, this is carried out proving uniform estimates independent of the parameter \(\varepsilon \), and the passage to the limit is performed through monotonicity techniques. Finally, Sect. 5 contains the proof of the regularity results: in the first one we show that additional requirements on the momentum of the data yield, in the case of the classical double-well potential, additional space-time estimates on the chemical potential and on the nonlinearity. The proof is based strongly on the Sobolev embeddings theorems and a generalized Itô’s formula for the problem. Finally, in the second regularity result the main idea is that if the data of the problem are more regular, then we are able to give appropriate sense to an Itô-type formula (better said, inequality) for the Ginzburg–Landau free-energy functional associated to the system. Starting with the viscous case, we show further uniform estimates on the solutions yielding the desired regularity result. Furthermore, passing to the limit as \(\varepsilon \searrow 0\) in the estimates which are independent of the viscosity parameter yields some refined regularity properties also for the pure case thanks to the asymptotic result already proved. As a main consequence, we are able to give sufficient conditions yielding \(H^3\)-regularity in space for the solution.
2 General Setting and Main Results
Let \(D\subseteq \mathbb {R}^N\) (\(N=2,3\)) be a smooth bounded domain, \(T>0\) a fixed final time and set \(Q:=(0,T)\times D\). We shall work on an underlying filtered probability space \((\Omega ,\mathscr {F}, (\mathscr {F}_t)_{t\in [0,T]}, \mathbb {P})\) satisfying the usual conditions, i.e. the filtration is saturated and right-continuous. Moreover, U is a separable Hilbert space and W is a cylindrical Wiener process on U.
Throughout the work, the spaces of Bochner-integrable functions shall be denoted by the classical symbols \(L^p(0,T; E)\) and \(L^p(\Omega ; E)\), where E can be an arbitrary Banach space. The spaces of bounded linear operators and Hilbert-Schmidt operators are indicated by \(\mathscr {L}(E_1, E_2)\) and \(\mathscr {L}^2(E_1, E_2)\), respectively, where \(E_1\) and \(E_2\) are Hilbert spaces. Moreover, we shall denote duality pairings, scalar products and norms in Banach and Hilbert spaces with the symbols \(\left<\cdot ,\cdot \right>\), \((\cdot ,\cdot )\) and \(\left\| \cdot \right\| \), respectively, specifying the space in consideration through a subscript. We shall also use the notation \(a\lesssim b\) for any \(a,b\ge 0\) to say that there exists \(C>0\) such that \(a\le Cb\): when C depends explicitly on a specific quantity we shall indicate it explicitly through a subscript.
We shall use the following definitions:
In particular, \(V_1\hookrightarrow H\) densely, and we identify H with \(H^*\) in the usual way, so that \((V_1,H,V_1^*)\) is a Hilbert triplet. For every element \(v\in V_1^*\), the mean of v on D is denoted by \(v_D:=\frac{1}{|D|}\left<v,1\right>_{V_1}\), and we set
for the subspaces of \(V_1^*\), H and \(V_1\) formed of the null-mean elements. Let us recall also that, thanks to the Poincaré-Wirtinger inequality and the classical elliptic regularity results for the Laplace operator (see [46, Thm. 3.2]), two equivalent norms on \(V_1\) and \(V_2\) are given by, respectively,
The Laplace operator with homogeneous Neumann boundary conditions is defined as
We recall that, since \(\left\| \cdot \right\| _1\) is equivalent to the usual norm in \(V_1\), the restriction of \(-\Delta \) to \(V_{1,0}\) is an isomorphism between \(V_{1,0}\) and \(V_{1,0}^*\). In particular, it is well defined its inverse
where for every \(v\in V^*_{1,0}\), the element \({\mathcal {N}}v\in V_{1,0}\) is the unique solution with null mean to the generalized Neumann problem
It is clear that \({\mathcal {N}}\) is an isomorphism between \(V_{1,0}^*\) and \(V_{1,0}\) satisfying
Moreover, we also recall that an equivalent norm on \(V_1^*\) is given by
and that for every \(\eta >0\) there exists \(C_\eta >0\) such that
Finally, for every \(v\in H^1(0,T; V_{1,0}^*)\) we have
For any further detail, the reader can refer to [14, pp. 979–980].
We introduce the following space, for any \(p,q\in [1,+\infty )\),
and define the operator
The following hypotheses will be in order throughout the paper:
-
(H1)
\(\beta :\mathbb {R}\rightarrow 2^\mathbb {R}\) is a maximal monotone graph, with \(0\in \beta (0)\) and \(D(\beta )=\mathbb {R}\). This implies in particular that \(\beta \) is the subdifferential of a continuous convex function \({\widehat{\beta }}:\mathbb {R}\rightarrow [0,+\infty )\) such that \({\widehat{\beta }}(0)=0\). We shall also assume a symmetry-like condition on \({\widehat{\beta }}\) of the form
$$\begin{aligned} \limsup _{|r|\rightarrow +\infty }\frac{{\widehat{\beta }}(r)}{{\widehat{\beta }}(-r)}<+\infty \,, \end{aligned}$$which is trivially satisfied if \({\widehat{\beta }}\) is an even function for example. If we denote by \(\widehat{\beta ^{-1}}\) the convex conjugate of \({\widehat{\beta }}\), i.e.
$$\begin{aligned} \widehat{\beta ^{-1}}:\mathbb {R}\rightarrow [0,+\infty ]\,, \qquad \widehat{\beta ^{-1}}(r):=\sup _{s\in \mathbb {R}}\{sr-{\widehat{\beta }}(s)\}\,, \quad r\in \mathbb {R}\,, \end{aligned}$$then it is well-known that \(\partial \widehat{\beta ^{-1}}=\beta ^{-1}\), and the fact that \(\beta \) is everywhere defined on \(\mathbb {R}\) implies that \(\widehat{\beta ^{-1}}\) is superlinear at infinity, i.e.
$$\begin{aligned} \lim _{|r|\rightarrow +\infty }\frac{\widehat{\beta ^{-1}}(r)}{r}=+\infty \,. \end{aligned}$$ -
(H2)
\(\pi :\mathbb {R}\rightarrow \mathbb {R}\) is a Lipschitz-continuous function such that \(\pi (0)=0\). We shall denote the Lipschitz constant of \(\pi \) by \(C_{\pi }\) and we define \({\widehat{\pi }}:\mathbb {R}\rightarrow \mathbb {R}\) as \({\widehat{\pi }}(r):=\int _0^r\pi (s)\,ds\).
-
(H3)
\(g:\Omega \times [0,T]\rightarrow H\) is progressively measurable and \(g\in L^2(\Omega \times (0,T); H)\).
-
(H4)
\(u_0 \in L^2(\Omega , \mathscr {F}_0, \mathbb {P}; H)\), \(\varepsilon u_0 \in L^2(\Omega , \mathscr {F}_0,\mathbb {P}; V_1)\) and \({\widehat{\beta }}(\alpha (u_0)_D)\in L^1(\Omega )\) for all \(\alpha >0\). Note that the last requirement on \(u_0\) can be reformulated by saying that the mean of \(u_0\) on D must belong to the small Orlicz space generated by \({\widehat{\beta }}\) on \(\Omega \): the formulation with an arbitrary positive parameter \(\alpha \) is crucial since the potential \({\widehat{\beta }}\) is allowed to be super-homogeneous as well. Such assumption is not restrictive and is satisfied for example when \((u_0)_D\) is non-random. If \({\widehat{\beta }}\) is a polynomial, then the last requirement amounts to saying that \((u_0)_D\) has finite moment of a certain order.
We are now ready to give the definition of strong solution for the problem. Fix \(\varepsilon >0\): recall that we want to study the problem
with homogeneous Neumann conditions on u and w. In order to understand what a reasonable weak formulation of the problem can be, we argue formally in the first place. Assume that \((u,\xi )\) is a sufficiently regular solution to our problem: this means that
A weak formulation of the problem can be obtained multiplying by a suitable test function \(\varphi \) and integrating by parts on D. In particular, taking into account the boundary conditions of u and w, we see that if \(\partial _\mathbf{n}\varphi =0\), then
Due to the singularity of \(\beta \), we cannot expect \(\xi \) (hence also w) to be H-valued, but only \(L^1(D)\)-valued. Consequently, the choice of the space of test functions should also guarantee at least that \(\Delta \varphi \in L^\infty (D)\). For example, we can take \(\varphi \in V_4\), which ensures both that \(\partial _\mathbf{n}\varphi =0\) and, thanks to the Sobolev embeddings, that \(\Delta \varphi \in H^2(D)\hookrightarrow L^\infty (D)\). Let us now state the definition of strong solution for the problem in a rigorous way.
Definition 2.1
(Strong solution) Let \(\varepsilon \ge 0\). A strong solution to (1.1)–(1.4) is a triplet \((u, w, \xi )\), where u is an H-valued predictable process, w is a \(L^1(D)\)-valued adapted process and \(\xi \) is a \(L^1(D)\)-valued predictable process, such that
and, for every \(t\in [0,T]\), \(\mathbb {P}\)-almost surely,
We collect now the main results of the paper. The first two results deal with the well-posedness of the problem in the case of additive and multiplicative noise. We prefer to separate the two cases since with additive noise the stochastic integrand is allowed to be more general, while with multiplicative noise it is forced to take values in the space of mean-null elements (see also Remark 2.3). The pure and viscous cases are analyzed simultaneously by considering \(\varepsilon \ge 0\).
Theorem 2.2
(Well-posedness, additive noise) Let \(\varepsilon \ge 0\), \((u_0, g)\) satisfy (H1)–(H4) and
Then the problem (1.1)–(1.4) admits a strong solution. Furthermore, for every \(p\in [1,2]\) there exists a constant \(K>0\), independent of \(\varepsilon \), such that if \((u_0^1, g_1, B_1)\) and \((u_0^2, g_2, B_2)\) satisfy (H1)–(H4), (2.1)–(2.2) and
then, for any respective strong solutions \((u_1, w_1, \xi _1)\) and \((u_2, w_2, \xi _2)\) to (1.1)–(1.4),
In particular, (2.3) is true if \(B_1\) and \(B_2\) take values in \(\mathscr {L}^2(U, V_{1,0}^*)\) and \((u_0^1)_D=(u_0^2)_D\).
Remark 2.3
Note that the assumptions (2.1)–(2.2) allow the operator B to take values in the larger space \(\mathscr {L}^2(U,H)\). This is a generalization with respect to the classical results dealing with the stochastic Cahn–Hilliard equation, which usually require that B takes values in \(\mathscr {L}^2(U,H_0)\) instead: see for example [24, 62]. This is usually done in order to ensure the conservation of the mean of u in the system: in this work, we show however that in case of additive noise this is not necessary, provided that a suitable control on the \({\widehat{\beta }}\)-moment of \((B\cdot W)_D\) holds. Of course, if B is \(\mathscr {L}^2(U, H_0)\)-valued, hypothesis (2.2) is clearly satisfied. Furthermore, note that if \({\widehat{\beta }}\) is controlled by a polynomial of order p, then by homogeneity it is not restrictive to consider only the case \(\alpha =1\), and it is readily seen that (2.2) is true if
which can be easily checked in turn through the Jensen and Burkholder–Davis–Gundy inequalities for example.
Theorem 2.4
(Well-posedness, multiplicative noise) Let \(\varepsilon \ge 0\) and \((u_0, g)\) satisfy (H1)–(H4). Let also \(B:\Omega \times [0,T]\times V_1\rightarrow \mathscr {L}^2(U, H_0)\) be progressively measurable, and assume that there exists a constant \(N_B>0\) and an adapted process \(f\in L^1(\Omega \times (0,T))\) such that, for every \((\omega ,t)\in \Omega \times [0,T]\),
Then the problem (1.1)–(1.4) admits a strong solution. Furthermore, for every \(p\in [1,2]\) there exists a constant \(K>0\), independent of \(\varepsilon \), such that if \((u_0^1, g_1)\) and \((u_0^2, g_2)\) satisfy (H1)–(H4) and
then, for any respective strong solutions \((u_1, w_1, \xi _1)\) and \((u_2, w_2, \xi _2)\) to (1.1)–(1.4),
Remark 2.5
Let us mention that the well-posedness result implies that the solution map associating the data \((u_0, g)\) to the (unique) solution component u can be extended to the spaces
so that one could possibly define an even weaker concept of solution by performing classical density arguments. This basically corresponds to considering the evolution system exclusively on the dual space \(V_1^*\), with no further regularity a priori.
The next two results concern the vanishing viscosity limit of the problem as \(\varepsilon \searrow 0\), in the case of both additive and multiplicative noise. In particular, we prove that any strong solution to the viscous problem converges in suitable topologies to a strong solution of the pure equation as the viscosity coefficient \(\varepsilon \) goes to 0.
Theorem 2.6
(Asymptotics as \(\varepsilon \searrow 0\), additive noise) Assume (H1)–(H3), and let \(u_0\in L^2(\Omega , \mathscr {F}_0, \mathbb {P}; H)\) and \(B\in L^2(\Omega \times (0,T); \mathscr {L}^2(U, H))\) be progressively measurable. Suppose also that
are such that
For any \(\varepsilon >0\), let \((u_\varepsilon ,w_\varepsilon ,\xi _\varepsilon )\) be any strong solutions to problem (1.1)–(1.4) with data \((u_{0\varepsilon }, g_\varepsilon , B_\varepsilon )\). Then there exists a strong solution \((u,w,\xi )\) to (1.1)–(1.4) with data \((u_0,g,B)\) in the case \(\varepsilon =0\) such that, as \(\varepsilon \searrow 0\):
Theorem 2.7
(Asymptotics as \(\varepsilon \searrow 0\), multiplicative noise) Assume (H1)–(H3) and let \(u_0\in L^2(\Omega , \mathscr {F}_0, \mathbb {P}; H)\) and \(B:\Omega \times [0,T]\times V_1\rightarrow \mathscr {L}^2(U, H_0)\) progressively measurable satisfying (2.4)–(2.5) (with the choice \(\varepsilon =0\)). Let also \((u_{0\varepsilon })_{\varepsilon >0}\) and \((g_\varepsilon )_{\varepsilon >0}\) satisfy conditions (2.7)–(2.9) and
For any \(\varepsilon >0\), let \((u_\varepsilon ,w_\varepsilon ,\xi _\varepsilon )\) be any strong solutions to problem (1.1)–(1.4) with multiplicative noise B and data \((u_{0\varepsilon }, g_\varepsilon )\). Then there exists a strong solution \((u,w,\xi )\) to (1.1)–(1.4) with multiplicative noise B and data \((u_0,g)\) in the case \(\varepsilon =0\) such that, as \(\varepsilon \searrow 0\), the convergences of Theorem 2.6 hold.
Remark 2.8
Let us comment on the compatibility assumptions (2.11) and (2.12), which require the approximating families \((u_{0\varepsilon })_{\varepsilon }\) and \((B_\varepsilon )_\varepsilon \) to preserve the mean. Note that this is trivially satisfied for example in the classical case of elliptic-type approximations of the data: for instance, the choices \(u_{0\varepsilon }:=(I-\varepsilon \Delta )^{-1}u_0\) and \(B_\varepsilon :=(I-\varepsilon \Delta )^{-1}B\) easily fulfil the assumptions above.
The last results of this paper concern the regularity of the system. In the first regularity result that we present, we show how additional requirements on the moments of the data \((u_0,g,B)\) improve the corresponding regularity of the solutions in the classical case of a polynomial double-well potential of degree 4. This yields, in the viscous case, some \(L^2\)-estimates (in space and time) on w and on \(\xi \).
Theorem 2.9
(Regularity I) Let \(\varepsilon \ge 0\), \(p\ge 2\). Assume (H1)–(H4), (2.1)–(2.2) and
Then the unique strong solution \((u,w,\xi )\) to (1.1)–(1.4) also satisfies
Furthermore, in the case \(\varepsilon >0\) and \(p\ge 3\), if also
then
if also
then
We are now ready to present the second regularity result. Note that in the Definition 2.1 of strong solution the component w of the chemical potential is only \(L^1\) globally. However, this forces to have a variational formulation of the problem where all the spatial derivatives are shifted on the test function, whereas the most natural and classical formulation in the context of Cahn–Hilliard equations involves the gradient of the chemical potential w. Such a formulation is much more natural and effective both in terms of applications and from a mathematical point of view: indeed, it provides better estimates on the solutions, which are used in turn in a wide variety of concrete situations, such as, among all, optimal control problems. The possibility of writing a more natural variational formulation of the system, hence to give sense in a suitable way to \(\nabla w\), is strictly connected to the possibility of writing a Itô-type formula, or, better said, inequality, to the so-called free-energy functional of the system, defined as
In order to achieve so, further assumptions on the data are needed. We collect such a regularity result here.
Theorem 2.10
(Regularity II) Let \(\varepsilon \ge 0\), \(q\ge 2\). Assume (H1)–(H4), (2.1)–(2.2) and
Assume also one condition between (2.20)–(2.21) and one between (2.22)–(2.23), where
and
Then the unique strong solution \((u,w,\xi )\) to (1.1)–(1.4) satisfies
and the following variational formulation of (1.1)–(1.4) holds:
for every \(t\in [0,T]\) and almost every \(t\in (0,T)\), respectively, \(\mathbb {P}\)-almost surely. Furthermore if (2.22) is in order and \(q\ge 3\), it also holds that
If also \(\varepsilon =0\) we have
Remark 2.11
Let us stress that the regularity result obtained here allows to give a natural variational formulation to the problem which is more usable in practice in the context of Cahn–Hilliard-related problem (for example, optimal control problems). The variety of assumptions provided on \(\beta \) and B allow also to obtain such regularity properties also in the degenerate cases where B has not null-mean and \(\beta \) is not necessarily a polynomial function. We point out that the hypotheses on the operator B are satisfied, for example, when B is independent of \(\omega \) and t, and takes values in the smoother spaces of the form \(\mathscr {L}^2(U,V_s)\) for a suitable s. More specifically, the choice between (2.20)–(2.21) is motivated by the wish of giving an appropriate regularity result also in the more difficult case where B is not necessarily of null mean. On the other side, in (2.22)–(2.23) we are distinguishing between the possibly different growth of \(\beta \): the first case is the classical one corresponding to a polynomial double-well potential of degree 4, while in the second we only require \(\beta '\) to be controlled by \({\widehat{\beta }}\), allowing thus also first-order exponential growth for example.
Finally, the combination of Theorems 2.9–2.10 yields as a direct consequence some refined regularity results for the solutions.
Corollary 2.12
(Further regularity) Let \(\varepsilon =0\) and \(p,q\ge 3\). Assume the hypotheses (H1)–(H4), (2.1)–(2.2), (2.15)–(2.19), (2.22), (2.13)–(2.14) and one condition between (2.20)–(2.21). Then the unique strong solution \((u,w,\xi )\) to (1.1)–(1.4) satisfies
3 Well-Posedness
This section is devoted to the proof of well-posedness in the viscous case \(\varepsilon >0\) (the pure case \(\varepsilon =0\) has been studied in [62]).
We shall consider first the additive noise case, i.e. when B is a \(\mathscr {L}^2(U,H)\)-valued progressively measurable process such that
The idea to prove existence of solutions is to use a double approximation on the data of the problem: the first one consists is smoothing the coefficient B is a suitable way, and the second is the natural Yosida approximation on the nonlinearity. In order to avoid heavy notations, we proceed in the following way: we assume a further regularity on B is a first step, namely that
and we prove well-posedness regularizing the nonlinearity \(\beta \) through its Yosida approximation. Finally, we remove the additional assumption (3.1) using a second approximation of elliptic type on the noise.
The generalization to multiplicative noise is carried out at the end of the section.
Let us work now under the additional assumption (3.1) and \(\varepsilon >0\) fixed.
3.1 The Approximation
For any positive \(\lambda \), we denote by \(\beta _\lambda :\mathbb {R}\rightarrow \mathbb {R}\) and \({\widehat{\beta }}_\lambda :\mathbb {R}\rightarrow [0,+\infty )\) the Yosida approximation of \(\beta \) and the Moreau–Yosida regularization of \({\widehat{\beta }}\), respectively. The approximated problem is the following:
Bearing in mind Definition 2.1, a strong solution to the approximated problem is a couple \((u_\lambda , w_\lambda )\), where \(u_\lambda \) is a \(V_1\)-valued adapted process, \(w_\lambda \) is an H-valued adapted process, such that
and satisfying, for every \(t\in [0,T]\), \(\mathbb {P}\)-almost surely,
It is natural introduce the \(V_1\)-bilinear form
and to define the operator \({\mathcal {A}}_\lambda :\Omega \times [0,T]\times V_2\rightarrow V_2^*\) as
Setting also \(B_\varepsilon :=(I-\varepsilon \Delta )^{-1}B\), it is readily seen that the variational formulation of the approximated problem can be rewritten as
for every \(\varphi \in V_2\).
We shall need some properties of \(\mathcal {A}_\lambda \), collected in the following lemma.
Lemma 3.1
For every \(\lambda >0\), the operator \({\mathcal {A}}_\lambda :\Omega \times [0,T]\times V_2\rightarrow V_2^*\) is progressively measurable and satisfies the following conditions:
-
hemicontinuity: the map \(r\mapsto {}_{V_2^*}\left<{\mathcal {A}}_\lambda (\omega ,t,v_1+r v_2),\varphi \right>_{V_2}\), \(r\in \mathbb {R}\), is continuous for every \((\omega ,t)\in \Omega \times [0,T]\) and \(v_1,v_2,\varphi \in V_2\);
-
weak monotonicity: there exists \(c>0\) such that, for every \((\omega ,t)\in \Omega \times [0,T]\),
$$\begin{aligned} {}_{V_2^*}\left<{\mathcal {A}}_\lambda (\omega ,t,v_1)-{\mathcal {A}}_\lambda (\omega ,t,v_2),v_1-v_2\right>_{V_2} \ge -c\left\| v_1-v_2\right\| _{H}^2 \qquad \forall \,v_1,v_2\in V_2\,; \end{aligned}$$ -
weak coercivity: there exist \(c_1,c_1'>0\) and an adapted process \(f_1 \in L^1(\Omega \times (0,T))\) such that, for every \((\omega ,t)\in \Omega \times [0,T]\),
$$\begin{aligned} {}_{V_2^*}\left<{\mathcal {A}}_\lambda (\omega ,t,v),v\right>_{V_2}\ge c_1\left\| v\right\| ^2_{V_2} - c_1'\left\| v\right\| ^2_{H} - f_1(\omega ,t) \qquad \forall \,v\in V_2\,; \end{aligned}$$ -
weak boundedness: there exists \(c_2>0\) and an adapted process \(f_2 \in L^1(\Omega \times (0,T))\) such that, for every \((\omega ,t)\in \Omega \times [0,T]\),
$$\begin{aligned} \left\| {\mathcal {A}}_\lambda (\omega ,t,v)\right\| ^2_{V_2^*}\le c_2\left\| v\right\| ^2_{V_2} + f_2(\omega ,t) \qquad \forall \, v\in V_2\,. \end{aligned}$$
Proof
We refer to [62, Lemma 3.1]: the proof is based on the fact that \(V_1\hookrightarrow H\) and the Lipschitz continuity of \(\beta _\lambda \) and \(\pi \). \(\square \)
We can prove now existence and uniqueness of an approximate solution \((u_\lambda ,w_\lambda )\).
Proposition 3.2
In the current setting, there exists a unique pair \((u_\lambda ,w_\lambda )\) with
such that, for every \(t\in [0,T]\), \(\mathbb {P}\)-almost surely,
Proof
Since \((\cdot ,\cdot )_{1,\varepsilon }\) defines an equivalent scalar product on \(V_1\), we can identify the Hilbert space \(V_1\) with its dual \(V_1^*\) through the isomorphism \(I-\varepsilon \Delta \). Secondly, since \(V_2\hookrightarrow V_1\) continuously and densely, then \(V_1^*\) is canonically embedded in \(V_2^*\) through the dualization given by \(I-\varepsilon \Delta \), namely
where all inclusions are continuous and dense. This means that every \(v\in V_1\) belongs also to \(V_2^*\) and the duality is given by
Working on the Hilbert triplet \((V_2, V_1, V_2^*)\) with this given dualization of \(V_1\), thanks to Lemma 3.1, the facts that the norm \(\left\| \cdot \right\| _{1,\varepsilon }\) is equivalent to \(\left\| \cdot \right\| _{V_1}\) and \(V_1\hookrightarrow H\) continuously, the operator \({\mathcal {A}}_\lambda \) continues to satisfy the usual hypotheses of hemicontinuity, monotonicity, coercivity and boundedness also on the Hilbert triple \((V_2,V_1,V_2^*)\) with the dualization given by \(I-\varepsilon \Delta \). Hence, the thesis follows by the classical variational theory (see [47, 59, 60]). \(\square \)
Remark 3.3
Since we have stated in the introduction that H is identified to its dual in the canonical way, we want to spend a few words on the dualization introduced in the proof of Proposition 3.2, as this may cause some confusion. The dualization of \(V_1\) given by \(I-\varepsilon \Delta \) is confined only to the proof of the Proposition 3.2 as a tool in order to obtain directly the required regularity on the approximated solutions avoiding further technicalities as finite-dimensional approximations. Throughout the rest of the paper, we shall use the dualization on H introduced in the introduction.
Let us stress that the definition of the operator \(\mathcal {A_\lambda }:\Omega \times [0,T]\times V_2\rightarrow V_2^*\) given above is independent on the specific dualization chosen on H rather that on \(V_1\). What actually depends on the particular “pivot” space in the following fact: if we identify H to its dual in the usual way, then \({\mathcal {A}}_\lambda \) is the weak realization of the (random and time-dependent) unbounded operator \(A_{\lambda }^H\) on H given by
whereas if we identify \(V_1\) with its dual through \(I-\varepsilon \Delta \), then \({\mathcal {A}}_\lambda \) is the weak formulation of the unbounded operator \(A_{\lambda \varepsilon }^{V_1}\) on \(V_1\) defined as
Indeed, in the former case this follows immediately by integration by parts. In the latter case, for every \((\omega ,t)\in \Omega \times [0,T]\), \(v\in D(A^{V_1}_{\lambda \varepsilon }(\omega ,t,\cdot ))\) and \(\varphi \in V_2\), we have \(A^{V_1}_{\lambda \varepsilon }(\omega ,t,v)\in V_1\): hence, recalling that \(V_1\hookrightarrow V_2^*\) through the dualization given by \(I-\varepsilon \Delta \),
so that \(A^{V_1}_{\lambda \varepsilon }\) extends continuously to the weak operator \({\mathcal {A}}_\lambda \).
In a formal way, but perhaps more explicative, when we choose the dualization on \(V_1\) we are applying the operator \((I-\varepsilon \Delta )^{-1}\) to the approximated equation (3.2), in order to shift the evolution from \(V_1^*\) to \(V_1\): this explains why the stochastic integrand on the right-hand side is \((I-\varepsilon \Delta )^{-1}B\). In other words, if we use the dualization on H then the approximated equation formally reads
while if we use the dualization on \(V_1\)(with scalar product \((\cdot ,\cdot )_{1,\varepsilon }\)) it formally reads
As we have already pointed out, the dualization on \(V_1\) through \(I-\varepsilon \Delta \) is confined only the proof of Proposition 3.2, and we shall keep the dualization on H from now on.
3.2 Pathwise Estimates
In this section we prove pathwise estimates on the approximated solutions, independently of the parameter \(\lambda \). The term “pathwise” refers here to the fact that \(\omega \) is fixed in a suitable set of probability 1 in \(\Omega \). First of all, we can rewrite the approximated equation as
First of all, testing (3.6) by \(\varphi =\frac{1}{|D|}\), since the operator \(R_\varepsilon ^{-1}=(I-\varepsilon \Delta )^{-1}\) preserves the mean we infer that
where \(m\in L^2(\Omega ; C^0([0,T]))\) thanks to the properties of the stochastic integral. Similarly,
so that we can define \(m_\varepsilon :=(u_0)_D+B_\varepsilon \cdot W \in L^2(\Omega ; C^0([0,T]; V_{1}))\). Taking these remarks into account, thanks to the assumptions (H4) and (3.1) on \(u_0\) and B, respectively, there is \(\Omega '\in \mathscr {F}\) (independent of both \(\lambda \) and \(\varepsilon \), and depending only on the initial data) with \(\mathbb {P}(\Omega ')=1\) such that, for every \(\omega \in \Omega '\),
Let us fix now \(\omega \in \Omega '\): in the sequel, we do not write the dependence on \(\omega \) explicitely.
We shall need the following lemma.
Lemma 3.4
The operator
is linear, symmetric, monotone and continuous. Moreover, we have \(\phi _\varepsilon =D\Phi _\varepsilon \) in the sense of Fréchet, where \(\Phi _\varepsilon :V^*_1\rightarrow [0,+\infty )\) is defined as
Proof
The map \(\phi _\varepsilon \) is well defined by definition of \({\mathcal {N}}\), and is trivially continuous and linear: hence, we only have to check monotonicity. For every \(v\in V_1^*\), by definition of \({\mathcal {N}}\) and \(R_\varepsilon ^{-1}\) we have
Hence, \(\phi _\varepsilon \) is maximal monotone and a similar computation shows that \(\phi _\varepsilon =\partial \Phi _\varepsilon \). Since \(\phi _\varepsilon \) is also linear and continuous, \(\Phi _\varepsilon \) is Fréchet differentiable and \(D\Phi _\varepsilon =\phi _\varepsilon \). \(\square \)
We test (3.6) by \(\phi _\varepsilon (R_\varepsilon (u_\lambda -B_\varepsilon \cdot W))\), and we obtain
Now, note that \((R_\varepsilon (u_\lambda -B_\varepsilon \cdot W))_D = (u_\lambda -B_\varepsilon \cdot W)_D\) and
hence, rearranging the terms we have
Integrating by parts we infer that
Using the definition of Yosida approximation and the generalized Young inequality on the last term on the left-hand side we get
while the Young inequality on the right-hand side yields
Moreover, by the Lipschitz continuity of \(\pi \) and thanks to the properties of \(\left\| \cdot \right\| _*\) we have, for every \(\sigma >0\),
Choosing \(\sigma >0\) sufficiently small, using the Gronwall lemma and rearranging all the terms, we deduce that for every \(t\in [0,T]\)
where the implicit constant is independent of both \(\lambda \) and \(\varepsilon \). Now note that the right-hand side is finite for every \(\omega \in \Omega '\): indeed, since \(m_\varepsilon =(u_0)_D + B_\varepsilon \cdot W\), by the contraction properties of \((I-\varepsilon \Delta )^{-1}\) on \(V_1^*\), H and \(V_1\) we have
while the contraction property of \((I-\varepsilon \Delta )^{-1}\) on \(L^\infty (D)\) yield
The right-hand sides are finite in \(\Omega '\) thanks to the assumptions on \(u_0\) and B. We deduce that for every \(\omega \in \Omega '\), there is \(M_\omega >0\), independent of \(\lambda \) and \(\varepsilon \), such that
Let us perform the second estimate now. We test (3.6) by \(u_\lambda -B_\varepsilon \cdot W\):
Now, rearranging the terms we have
so that the Young inequality, the regularities of g and B and the fact that \((I-\varepsilon \Delta )^{-1}\) is non-expansive on H, \(V_1\) and \(V_2\) yield
where the implicit constants are independent of both \(\lambda \) and \(\varepsilon \). Noting that, by the symmetry-like assumption in (H1),
all the terms on the right-hand side are finite in \(\Omega '\). Hence, for every \(\omega \in \Omega '\) we also have
Furthermore, for every \(\varphi \in V_4\) and a.e. \(t\in (0,T)\), since \(V_4\hookrightarrow W^{2,\infty }(D)\) we have
Now, by (3.8) and the fact that \(\widehat{\beta ^{-1}}\) is superlinear, we know that \((\beta _\lambda (u_\lambda ))_\lambda \) is bounded in \(L^1(Q)\): hence, by (3.7)–(3.9) and by comparison in (3.6) we infer that
3.3 Estimates in Expectation
We prove here estimates in expectations on the approximated solutions: the idea is to re-perform the same estimates of Sect. 3.2 using Itô’s formula instead of a path-by-path argument: recall that we have
Bearing in mind Lemma 3.4, due to the linearity and continuity of \(\phi _\varepsilon \), we have that \(\Phi _\varepsilon \in C^2(V_1^*)\). It is clear that \(\Phi _\varepsilon \) and \(D\Phi _\varepsilon =\phi _\varepsilon \) are bounded on bounded subsets of \(V_1^*\), and the second Fréchet derivative of \(\Phi _\varepsilon \), i.e.
is constant in \(V_1^*\). Moreover, \(\phi _\varepsilon \) is also linear and continuous from \(V_1^*\) to \(V_2\). Hence, we can apply Itô’s formula to \(\Phi _\varepsilon (u_\lambda )\) in the variational framework (cf. [59, Thm. 4.2, p. 65]), which yields, for every \(t\in [0,T]\), \(\mathbb {P}\)-almost surely,
Rearranging the terms and using the same computations based on the Young inequality and the Lipschitz continuity of \(\pi \) as in Sect. 3.2 we deduce that
Now, by the properties of \(\left\| \cdot \right\| _*\) we have
for every \(\sigma >0\). Moreover, by the properties of \(\phi _\varepsilon \) and since \(R_\varepsilon ^{-1}\) is contraction on \(V_1^*\), we have
Taking supremum in time and expectations, we estimate the last term on the right-hand side using the Burkholder–Davis–Gundy and Young inequalities as
where, by definition of \({\mathcal {N}}\) and \(R_\varepsilon ^{-1}\),
where all the implicit constants are independent of \(\lambda \) and \(\varepsilon \). Choosing \(\sigma \) sufficiently small, rearranging the terms and using the Gronwall lemma yield
Note that all the terms on the right-hand side are finite by the assumptions on g, \(u_0\) and B. Indeed, we have that
so that \(\nabla m=0\), and, by convexity of \({\widehat{\beta }}\),
We deduce that there exists a constant \(M>0\), independent of \(\lambda \) and \(\varepsilon \), such that
In order to deduce the further estimates on the solutions, we write Itô’s formula for the square of the \(\left\| \cdot \right\| _{1,\varepsilon }\)-norm in \(V_1\):
By the Burkholder–Davis–Gundy and Young inequality we have
for every \(\sigma >0\): hence, recalling also that
taking supremum in time and expectations, choosing \(\sigma >0\) sufficiently small, rearranging the terms thanks to the Young inequality and the Lipschitz-continuity of \(\pi \) yield
The Gronwall lemma implies that there exists \(M>0\), independent of \(\lambda \) and \(\varepsilon \), such that
3.4 The Passage to the Limit
Let us fix \(\omega \in \Omega '\). First of all, by the estimate (3.9) and the fact that \(B\cdot W(\omega ) \in C^0([0,T]; V_4)\), we have that \((u_\lambda -B_\varepsilon \cdot W)_\lambda \) is uniformly bounded in \(L^2(0,T; V_2)\), so that \((R_\varepsilon (u_\lambda -B_\varepsilon \cdot W))_\lambda \) is uniformly bounded in \(L^2(0,T; H)\). Hence, recalling (3.10), since \(V_2\hookrightarrow V_1\) and \(V_1^*\hookrightarrow V_2^*\) compactly, thanks to the classical compactness results by Aubin–Lions and Simon (see [64, Cor. 4, p. 85]) we infer that \((R_\varepsilon (u_\lambda -B_\varepsilon \cdot W))_\lambda \) is relatively strongly compact in \(V_1^*\): since \(\varepsilon \) is fixed, we deduce that
Secondly, since \(\widehat{\beta ^{-1}}\) is superlinear, the estimate (3.9) yields that \((\beta _\lambda (u_\lambda (\omega )))_\lambda \) is uniformly integrable in Q, hence also weakly relatively compact in \(L^1(Q)\) by the Dunford-Pettis theorem.
Taking these remarks into account, by (3.7)–(3.10) we deduce that there are
and a subsequence \(\lambda '=\lambda '(\omega )\) of \(\lambda \) such that, as \(\lambda '\searrow 0\),
From the strong convergence (3.17) and the Lipschitz-continuity of \(\pi \) it easily follows that
Moreover, owing to the result [5, Thm. 18, p. 126] by Brézis on the strong-weak closure of maximal monotone graphs, the strong convergence of \(u_\lambda (\omega )\) and the weak convergence of \(\beta _\lambda (u_\lambda (\omega ))\) ensure also that
Furthermore, by definition of Yosida approximation and resolvent, since \((\beta _\lambda (u_\lambda (\omega )))_\lambda \) is bounded in \(L^1(Q)\) and \(u_\lambda (\omega )\rightarrow u(\omega )\) in \(L^1(Q)\), we have
Hence, the estimate (3.8) together with the weak lower semicontinuity of the convex integrands yields
so that \({\widehat{\beta }}(u(\omega ))+ \widehat{\beta ^{-1}}(\xi (\omega )) \in L^1(Q)\).
Now, setting \(w:=-\Delta u + \xi + \pi (u) - g\), we have that \(w(\omega )\in L^1(Q)\) and \(w_\lambda (\omega )\rightharpoonup w(\omega )\) in \(L^1(Q)\). Consequently, for every \(\varphi \in V_4\), since \(\Delta \varphi \in H^2(\Omega )\hookrightarrow L^\infty (D)\), we have
By comparison in the approximated equation, we deduce that for every \(t\in [0,T]\)
so that \(R_\varepsilon u_\lambda (\omega ,t){\mathop {\rightharpoonup }\limits ^{*}}R_\varepsilon u(\omega ,t)\) in \(V_4^*\). Since \(u_\lambda (\omega )\) is bounded in \(L^\infty (0,T; H)\) and \(\varepsilon u_\lambda (\omega )\) is bounded in \(L^\infty (0,T; V_1)\), we deduce that \(u_\lambda (\omega ,t)\rightharpoonup u(\omega ,t)\) in H and \(\varepsilon u_\lambda (\omega ,t)\rightharpoonup \varepsilon u(\omega ,t)\) in \(V_1\) for every \(t\in [0,T]\). Letting \(\lambda \searrow 0\) in the approximated equation and recalling that \(\omega \in \Omega '\) is arbitrary, we infer that, \(\mathbb {P}\)-almost surely,
By comparison in the limit equation together with the fact that \(u \in L^\infty (0,T; H)\) and \(\varepsilon u\in L^\infty (0,T; V_1)\) \(\mathbb {P}\)-almost surely, we infer that \(u \in C^0_w([0,T]; H)\hookrightarrow C^0([0,T]; V_1^*)\) and \(\varepsilon u \in C^0_w([0,T]; V_1)\hookrightarrow C^0([0,T]; H)\) \(\mathbb {P}\)-almost surely.
Let us prove now some regularity properties of the triple \((u,w, \xi )\) with respect to \(\omega \). Indeed, as we have fixed \(\omega \in \Omega '\) in passing to the limit, the subsequences along which we have convergence could possibly depend on \(\omega \), hence any measurability information is lost as \(\lambda \searrow 0\). In order to recover measurability properties for the limiting processes, we first prove that the solution components u and \(\xi -\xi _D\) satisfying pointwise the limit equation are unique.
Let then \((u_i, w_i, \xi _i)\) such that, for \(i=1,2\), \(\mathbb {P}\)-almost surely,
Now, thanks to the classical elliptic regularity results, there is \(m\in \mathbb {N}\) such that \((I-\sigma \Delta )^{-m}\) maps continuously \(L^1(D)\) into \(V_4\) for every \(\sigma >0\). Fixing such m, taking as test function \(\varphi =(I-\sigma \Delta )^{-m}y\) for any arbitrary \(y\in H\), using the fact that \((I-\sigma \Delta )^{-m}\) is self-adjoint and commutes with \(-\Delta \), we deduce that
in the strong sense on H, where we have used the superscript \(\sigma \) to denote the action of \((I-\sigma \Delta )^{-m}\). Testing by the constant 1 it easily follows that \((u_1^\sigma -u_2^\sigma )_D=0\), so that testing by \(\phi _\varepsilon (R_\varepsilon (u_1^\sigma -u_2^\sigma ))={\mathcal {N}}(u_1^\sigma -u_2^\sigma )\) yields
from which, by definition of \(w_i^\sigma \) and the Lipschitz-continuity of \(\pi \),
We want to let \(\sigma \rightarrow 0\) in the previous inequality. Thanks to the properties of \((I-\sigma \Delta )^{-1}\) and the regularity of \(u_1-u_2\), it is readily seen that
and
Now, since \(\widehat{\beta ^{-1}}(\xi _2)\in L^1(Q)\), the symmetry assumption on \({\widehat{\beta }}\) ensures that there is \(\delta \in (0,1)\) such that \(\widehat{\beta ^{-1}}(\delta |\xi _2|)\in L^1(Q)\), as one can easily check. Hence, using the Young inequality, the symmetry of \({\widehat{\beta }}\) and the Jensen inequality for the positive operator \((I-\sigma \Delta )^{-1}\) (see [40] for reference), we have that
for a positive constant c depending only on \({\widehat{\beta }}\). Since the term in bracket on the right-hand side belongs to \(L^1(Q)\), the right-hand side converges in \(L^1(Q)\) by the properties of the resolvent, hence it is uniformly integrable. Consequently, we deduce that the family \(\{(\xi _1^\sigma -\xi _2^\sigma )(u_1^\sigma -u_2^\sigma )\}_\sigma \) is uniformly integrable in Q. By Vitali’s convergence theorem it follows that
Letting then \(\sigma \rightarrow 0\) we get that, for every \(\eta >0\),
Since \((u_1-u_2)_D=0\), the Poincaré inequality and the Gronwall lemma yield \(u_1=u_2\). By comparison in the equation we obtain then
Choosing \(\varphi ={\mathcal {N}}y\) for any arbitrary \(y\in V_2\cap V_{1,0}\) yields also \(\xi _1-(\xi _1)_D=\xi _2-(\xi _2)_D\).
The uniqueness of the solution components u and \(\xi -\xi _D\) imply by a classical argument of real analysis that the convergence of \(u_\lambda \) and \(\beta _\lambda (u_\lambda )-\beta _\lambda (u_\lambda )_D\) hold along the entire sequence \(\lambda \), independently of \(\omega \). This ensures in turn that u is a predictable \(V_1\)-valued process, progressively measurable in \(V_2\), weakly*-measurable in \(L^\infty (0,T; H)\), that \(\xi \) is a predictable \(L^1(D)\)-valued process and that w is progressively measurable and adapted in \(L^1(D)\). For a detailed argument of measurability, the reader can refer to [62, § 3.6].
Finally, by the weak-lower semicontinuity of the norms and the convex integrands, the estimates in expectations (3.11)–(3.13) imply that
and this completes the proof of existence of solutions with additive noise under the additional assumption (3.1).
3.5 Conclusion
As we have anticipated at the beginning of Sect. 3, we now remove the extra assumption (3.1) on the operator B. Let us suppose only that B is a \(\mathscr {L}^2(U,H)\)-progressively measurable process such that
For every \(n\in \mathbb {N}\), \(n>0\), let us define the \(\mathscr {L}(U,V_4)\)-valued process
which satisfies, as it is readily seen by classical elliptic regularity results, as \(n\rightarrow \infty \),
Now, for every \(n\in \mathbb {N}\), \(n>0\), let \((u_n,w_n, \xi _n)\) be the strong solution to the problem (1.1)–(1.4) with respect to the data \((u_0, g, B_n)\), as given by the proof just performed in the previous sections. Going back to Sect. 3.3, we notice that the estimates in expectation (3.11)–(3.13) only depend on the \(L^2(\Omega \times (0,T); \mathscr {L}^2(U, H))\)-norm of B: hence, since \((B_n)_n\) is uniformly bounded in \(L^2(\Omega \times (0,T); \mathscr {L}^2(U, H))\), by weak lower semicontinuity of the norms we infer that
Let us show a strong convergence for the sequence \((u_n)_n\). We define the operator
which clearly extends \(\Delta \) to \(L^1(D)\), i.e. \(-{\mathcal {L}}_{|V_1}=-\Delta \). With this notation, the solutions \((u_n, w_n, \xi _n)\) satisfy
Now, by elliptic regularity, there is \(m\in \mathbb {N}\) such that \((I-\sigma \Delta )^{-m}\in \mathscr {L}(L^1(D), V_4)\). Taking the difference between the equations at any arbitrary \(n,k\in \mathbb {N}\), \(n,k>0\), applying the operator \((I-\sigma \Delta )^{-m}\) and using the fact that \((I-\sigma \Delta )^{-m}\) commutes with \({\mathcal {L}}\), we get
where we have used again the superscript \(\sigma \) for the action of the resolvent \((I-\sigma \Delta )^{-m}\). Since \((u^\sigma _n-u_k^\sigma )_D=0\), the classical Itô’s formula for \(\Phi _\varepsilon (R_\varepsilon (u_n^\sigma -u_k^\sigma ))\) then yields, for every \(t\in [0,T]\), \(\mathbb {P}\)-almost surely,
Now, by the contraction properties of \((I-\sigma \Delta )^{-1}\) and Lipschitz-continuity of \(\pi \) we have
Arguing as in Sect. 3.3 we infer that
and similarly, for every \(\delta >0\),
Rearranging the terms, choosing \(\delta \) sufficiently small and using the Gronwall lemma we deduce that
We want to let \(\sigma \rightarrow 0\) in the last inequality. The first three terms converge to the corresponding ones without \(\sigma \) by the approximation properties of the operator \((I-\sigma \Delta )^{-1}\) (see for example [62, § 3.7]). Proceeding as in the previous section we also have the convergence
so that letting \(\sigma \rightarrow 0\) and employing the monotonicity of \(\beta \) we infer
where the implicit constant is independent of \(\varepsilon \), n and k. Since the right-hand side converges to 0 as \(n,k\rightarrow \infty \), we deduce the strong convergence for \((u_n)_n\) in the respective spaces. This information together with the estimates obtained at the beginning of this section allows to pass to the limit in the approximated equation as \(n\rightarrow \infty \) and deduce the existence of a strong solution for the limit problem, using again classical tools of convex analysis as in the previous section.
3.6 Continuous Dependence with Additive Noise
Let \((u_0^1, g_1, B_1)\) and \((u_0^2, g_2, B_2)\) satisfy the assumptions (H1)–(H4) and (2.1)–(2.3). Then testing the equation satisfied by the difference \(u_1-u_2\) by the constant 1 it is readily seen that \((u_1-u_2)_D=0\). Hence, arguing as in the previous Sect. 3.5, writing Itô’s formula for \(\Phi _\varepsilon (R_\varepsilon (u_1-u_2))\) we can infer that
The case \(p=2\) is immediate: estimating the terms on the right-hand side through the Young, Poincaré, Burkholder–Davis–Gundy inequalities exactly as in Sect. 3.5 yields
where the implicit constant is independent of \(\varepsilon \). In order to prove the result in general for \(p\in [1,2]\) it is enough to take the p/2-power in Itô’s formula, and proceed in the same way, getting
It is easy to check that the trace term on the right-hand side is bounded (modulo a positive constant independent of \(\varepsilon \)) by \(\left\| B_1-B_2\right\| ^p_{L^2(0,T; \mathscr {L}^2(U, V_1^*))}\). Furthermore, the Burkholder–Davis–Gundy inequality with exponent p/2 yields, for every \(\sigma >0\),
Taking expectations, choosing \(\sigma \) sufficiently small and employing again the Gronwall lemma, we obtain the desired result.
3.7 Existence with Multiplicative Noise
Let us focus now on the multiplicative noise case: let \((u_0, g, B)\) satisfy the assumpitons (H1)–(H4) and (2.4)–(2.5). For any progressively measurable \(V_1\)-valued process \(y\in L^2(\Omega \times (0,T); V_1)\), the linear growth assumption on B readily implies that \(B(\cdot , \cdot , y)\) is progressively measurable and that \(B(\cdot , \cdot , y)\in L^2(\Omega \times (0,T); \mathscr {L}^2(U, V_1^*))\). Hence, we are in the hypothesis of the additive noise case, and there exists a strong solution \((u_y, w_y, \xi _y)\) to the problem with respect to the data \((u_0, g, B(y))\). Since the solution component \(u_y\) is unique, for every \(T_0\in (0,T]\) it is well defined the map
such that \(\Gamma :y\mapsto u_y\). It is clear that \((u, w, \xi )\) is a strong solution on \([0,T_0]\) with multiplicative noise if and only if u is a fixed point for \(\Gamma \) and \((w, \xi )=(w_u, \xi _u)\).
Let \(y_1, y_2 \in L^2(\Omega \times (0,T_0); V_1)\) progressively measurable and set \(u_1:=\Gamma (y_1)\) and \(u_2:=\Gamma (y_2)\). Thanks to (2.6) and the fact that B is \(\mathscr {L}^2(U, V_{1,0}^*)\)-valued, we can apply the continuous dependence property proved in Sect. 3.6: using also the Lipschitz-continuity of B, we have that
This shows in particular that, for every \(T_0\in (0,T]\), the map \(\Gamma \) continuously extends in a canonical way to
and that \(\tilde{\Gamma }\) is a contraction on \(L^2(\Omega ; C^0([0,T_0]; V_1^*))\) provided that \(T_0\) is chosen sufficiently small. Hence, fixing such \(T_0>0\), there exists a unique \(u\in L^2(\Omega ; C^0([0,T_0]; V_1^*))\) such that \(u={\tilde{\Gamma }} u\). Moreover, since \(u={\tilde{u}}\in L^2(\Omega \times (0,T_0); V_1)\) by definition of \({\tilde{\Gamma }}\), we also deduce that \(u=\Gamma u \in L^2(\Omega ; C^0([0,T_0]; H))\cap L^2(\Omega ; L^\infty (0,T_0; V_1)) \cap L^2(\Omega \times (0,T_0); V_2)\) by definition of \(\Gamma \). Hence, u is a strong solution to the problem with multiplicative noise on \([0,T_0]\) together with some respective solution components \((w,\xi )\) (not necessarily unique). Now a strong solution on the whole interval [0, T] can be obtained by a classical patching argument on the subintervals \([T_0, 2T_0]\), ..., until T iterating the computations just performed.
3.8 Continuous Dependence with Multiplicative Noise
Let now \((u_0^1, g_1)\) and \((u_0^2, g_2)\) satisfy (H1)–(H4) and (2.3). The fact that B takes values in \(\mathscr {L}^2(U, V_{1,0}^*)\) and (2.3) imply in particular that
Hence, by the continuous dependence result with additive noise case and the Lipschitz continuity of B we have, for every \(T_0\in (0,T]\) and \(p\in [1,2]\),
where all the implicit constants are independent of \(\varepsilon \). Now the continuous dependence result follows choosing again \(T_0\) sufficiently small and by a patching argument.
4 Vanishing Viscosity Limit as \(\varepsilon \searrow 0\)
4.1 Additive Noise
We begin with the additive noise case: let us work thus in the framework of Theorem 2.6. We recall that \((u_\varepsilon , w_\varepsilon , \xi _\varepsilon )\) are strong solutions to problem (1.1)–(1.4) with respect to \(\varepsilon >0\) and data \((u_{0\varepsilon }, g_\varepsilon , B_\varepsilon )\). Note that thanks to the continuous dependence property contained in Theorem 2.2, the solution component \(u_\varepsilon \) is uniquely determined.
First of all, we assume that B satisfies the stronger assumption (3.1) and that \((B_\varepsilon )_\varepsilon \) is bounded in the space (3.1): we will show how to remove this further hypothesis later on. Going back to Sects. 3.2–3.3 and noting that the estimates (3.7)–(3.12) are independent of \(\varepsilon \), we deduce by lower semicontinuity that for every \(\omega \in \Omega '\) with \(\mathbb {P}(\Omega '=1)\) there is a positive constant \(M_\omega \) independent of \(\varepsilon \) such that
and similarly, for a positive constant M independent of \(\varepsilon \),
We fix now \(\omega \in \Omega '\). By the pathwise estimates, using similar arguments to the ones performed in Sect. 3.4, we deduce that \((R_\varepsilon (u_\varepsilon -B_\varepsilon \cdot W))_\varepsilon =(R_\varepsilon u_\varepsilon -B\cdot W)_\varepsilon \) is relatively compact in \(V_1^*\). Moreover, by definition of \(R_\varepsilon ^{-1}\) and the fact that \((u_\varepsilon )_\varepsilon \) is bounded in \(L^2(0,T; H)\), it follows that \((u_\varepsilon )_\varepsilon \) is relatively compact in \(V_1\). Hence, we infer the convergences
for certain \(u(\omega )\in L^\infty (0,T; H)\cap L^2(0,T; V_2)\), \(\xi (\omega )\in L^1(Q)\) and \(w(\omega )\in L^1(Q)\).
Let us show that \((u,\xi ,w)\) is a solution to the problem corresponding to \(\varepsilon =0\). Arguing again as in Sect. 3.4, we infer that u is a predictable H-valued process, progressively measurable adapted in \(V_2\) and with continuous trajectories in \(V_1^*\). Furthermore, the estimates in expectations yield the desired convergences for \(u_\varepsilon \): indeed, the weak convergences are immediate, while the strong convergence follows by a classical consequence of the Severini-Egorov theorem from the fact that \(u_\varepsilon \rightarrow u\) in \(L^2(0,T; V_1)\) \(\mathbb {P}\)-almost surely and the boundedness of \((u_\varepsilon )_\varepsilon \) in \(L^2(\Omega \times (0,T); V_1)\). As far as \(\xi \) is concerned, proceeding as in Sect. 3.4 we can choose \(\xi \) to be a predictable \(L^1(D)\)-valued process such that \(\xi _\varepsilon \rightharpoonup \xi \) in \(L^1(\Omega \times Q)\). A similar argument holds for w. It is also clear using the convergences of \((u_\varepsilon , w_\varepsilon , \xi _\varepsilon )\) that \((u,w,\xi )\) is a strong solution to the problem in the case \(\varepsilon =0\).
We show now that it is not restrictive to assume that (3.1) holds for the operators B and \((B_\varepsilon )_\varepsilon \). Indeed, if this is not the case, all the estimates in expectation on \((u_\varepsilon , w_\varepsilon , \xi _\varepsilon )\) continue to hold, as they depend only on the \(\mathscr {L}^2(U,H)\)-regularity of B (see for example Sect. 3.3). Hence, the weak convergences in Theorem 2.6 are still true, as well as \(\varepsilon u_\varepsilon \rightarrow 0\) in \(L^2(\Omega ; L^\infty (0,T; V_1))\). The problem is the strong convergence of \(u_\varepsilon \) in \(L^p(\Omega ; L^2(0,T; V_1))\). To this end, for every \(\delta >0\) we set \(B_\delta :=(I-\delta \Delta )^{-2}B\), which satisfies (3.1), and similarly \(B_{\varepsilon \delta }:=(I-\delta \Delta )^{-2}B_\varepsilon \), which is uniformly bounded in \(\varepsilon \) in the space (3.1). Let \((u_{\varepsilon \delta }, w_{\varepsilon \delta }, \xi _{\varepsilon \delta })\) and \((u_\delta , w_\delta , \xi _\delta )\) be any strong solutions with respect to the data \((u_{0\varepsilon }, g_\varepsilon , B_{\varepsilon \delta })\) and \((u_0, g, B_\delta )\), in the cases \(\varepsilon >0\) and \(\varepsilon =0\), respectively: since the first solution component is unique, note that \(u_\delta \) and \(u_{\varepsilon \delta }\) are uniquely determined. Since we have already proved the convergence result under the stronger assumption (3.1), we have that \(u_{\varepsilon \delta }\rightarrow u_\delta \) in \(L^p(\Omega ; L^2(0,T; V_1))\) for every \(p\in [1,2)\) and every \(\delta >0\), as \(\varepsilon \searrow 0\). Recalling the compatibility condition (2.11) and the fact that \((I-\delta \Delta )^{-2}\) preserves the mean, by the continuous dependence property of Theorem 2.2 we have
Since \(B_\delta \rightarrow B\) in \(L^2(\Omega \times (0,T); \mathscr {L}^2(U,H))\), the second term on the right-hand side can be made arbitrarily small choosing \(\delta \) small enough. With such a choice of \(\delta \) (fixed), the first and third terms converge to 0 as \(\varepsilon \searrow 0\), so that the strong convergence is proved.
4.2 Multiplicative Noise
Let us focus now on the multiplicative noise case. We work in the setting of Theorem 2.7: for every \(\varepsilon >0\), let \((u_\varepsilon , w_\varepsilon , \xi _\varepsilon )\) be any strong solution to the problem with \(\varepsilon >0\) with multiplicative noise given by the operator B and with respect to the data \((u_{0\varepsilon }, g_\varepsilon )\). Let us also denote by u the unique solution component of the limit problem with \(\varepsilon =0\) with multiplicative noise B and data \((u_0, g)\). Going back to Sect. 3.3, using the linear growth assumption of B it is not difficult to check that the estimates corresponding to (3.11)–(3.13) continue to hold for \((u_\varepsilon ,w_\varepsilon ,\xi _\varepsilon )\), i.e. there exists \(M>0\) independent of \(\varepsilon \) such that
These readily imply the weak convergences of \((u_\varepsilon ,w_\varepsilon ,\xi _\varepsilon )\) contained in Theorem 2.7, as well as \(\varepsilon u_\varepsilon \rightarrow 0\) in \(L^2(\Omega ; L^\infty (0,T; V_1))\). We only need to prove the strong convergence \(u_\varepsilon \rightarrow u\) in \(L^p(\Omega ; L^2(0,T; V_1))\). To this end, we denote by \(({\tilde{u}}_\varepsilon , {\tilde{w}}_\varepsilon , \tilde{\xi }_\varepsilon )\) a strong solution to the problem with \(\varepsilon >0\), data given by \((u_{0\varepsilon }, g)\), and additive noise given by B(u). Note that B(u) is an admissible choice thanks to the regularity of u and the linear growth assumption of B. Since we have already proved the additive noise case contained in Theorem 2.6 and the solution component u is unique, we have that \({\tilde{u}}_\varepsilon \rightarrow u\) in \(L^p(\Omega ; L^2(0,T; V_1))\) as \(\varepsilon \searrow 0\). For this reason, it is natural to show that the difference \(u_\varepsilon -{\tilde{u}}_\varepsilon \) converges to 0: since B is \(\mathscr {L}^2(U,H_0)\)-valued, the continuous dependence property for the problem with additive noise and \(\varepsilon >0\) and the Lipschitz continuity of B yield
Since T is arbitrary and we already know that the last term on the right-hand side converges to 0, the Gronwall lemma implies that \(u_\varepsilon -{\tilde{u}}_\varepsilon \rightarrow 0\) in \(L^p(\Omega ; L^2(0,T; V_1))\), from which the required convergence result. As in the case of additive noise, it is straightforward now to check that \((u,w,\xi )\) is a strong solution to the problem with multiplicative noise in the case \(\varepsilon =0\) and data \((u_0, g)\).
5 Regularity
In this last section we prove the regularity results contained in Theorems 2.9–2.10.
5.1 The First Result
Let us focus on the proof of Theorem 2.9. Suppose that \((u_0, g, B)\) have finite p-moments for a certain \(p\in [2,+\infty )\) as in the assumptions (2.13)–(2.14). Then we argue going back to Sect. 3.3: in the proof of estimate (3.13), we take the \(\frac{p}{2}\)-power of Itô’s formula for the square of the \(\left\| \cdot \right\| _{1,\varepsilon }\)-norm. Proceeding as in Sect. 3.6 we get
from which the desired estimate follows thanks to the Gronwall lemma.
Let us show now the additional regularities for w and \(\xi \) in the viscous case \(\varepsilon >0\). First of all, recalling that \(\beta \) has cubic growth by assumption, it easily follows that
and by comparison also
These readily imply that the families \((w_\lambda )_\lambda \) and \((\beta _\lambda (u_\lambda ))_\lambda \) are uniformly bounded in the space \(L^{p/3}(\Omega ; L^2(0,T; H))\), from which the thesis follows.
Finally, note that if \(\beta \in W^{1,\infty }_{loc}(\mathbb {R})\) and \(\beta '\) has quadratic growth, then
so that by the estimates already performed, the Hölder inequality and the fact that \(V_1\hookrightarrow L^6(D)\) we can infer that
which yields
with implicit constant independent of \(\lambda \) and \(\varepsilon \). Since \((u_\lambda )_\lambda \) is uniformly bounded in \(L^p(\Omega ; L^2(0,T; V_2))\) and \(L^{p}(\Omega ; L^\infty (0,T; V_1))\), we deduce by Hölder inequality that the right-hand is bounded in \(L^r(\Omega )\), with \(\frac{1}{r}=\frac{2}{p}+\frac{1}{p}=\frac{3}{p}\), i.e. for \(r=p/3\).
5.2 The Second Result
Let us turn the attention to Theorem 2.10. As we have anticipated, the idea is to write a Itô-type formula for the free-energy functional associated to the system. We start with the viscous case \(\varepsilon >0\).
Let \((u,w,\xi )\) be the strong solution to the problem, as in the setting of Theorem 2.10. Note that in this framework there is uniqueness of all the three solution components since \(\beta \) is assumed to be single-valued, hence the uniqueness of u implies the uniqueness of \(\xi \), and consequently of w. From Sect. 3 we know that \((u,w,\xi )\) can be obtained as limit in suitable topologies of some approximated solutions \((u_\lambda , w_\lambda , \xi _\lambda )\) solving the problem where \(\beta \) is replaced by its Yosida approximation \(\beta _\lambda \) and \(\xi _\lambda =\beta _\lambda (u_\lambda )\). If we denote the action of the resolvent \((I-\sigma \Delta )^{-2}\) by the superscript \(\sigma \), for every \(\sigma >0\), we have that
in the strong sense on H. Recall that \(w_\lambda ^\sigma =-\Delta u_\lambda ^\sigma + \beta _\lambda (u_\lambda )^\sigma +\pi (u_\lambda )^\sigma -g^\sigma \). We define similarly \(\mathbf{w}_\lambda ^\sigma :=-\Delta u_\lambda ^\sigma + \beta _\lambda (u_\lambda ^\sigma ) +\pi (u_\lambda ^\sigma )-g\).
We show here some further uniform estimates on \((u_\lambda , w_\lambda , \beta _\lambda (u_\lambda ))\) using the Ginzburg–Landau free-energy functional. It is natural to consider the regularized version of the functional \({\mathcal {E}}\) defined as
Let us show that \({\mathcal {E}}_\lambda \in C^2(V_1^*)\). It is clear that \({\mathcal {E}}_\lambda \) is Fréchet-differentiable with
from which it follows that \({\mathcal {E}}_\lambda \in C^1(V_1^*)\). Moreover, using the fact that \(V_1\hookrightarrow L^4(D)\), it is not difficult to check that \(D{\mathcal {E}}_\lambda \) is Fréchet-differentiable with \(D^2{\mathcal {E}}_\lambda :V_1^*\rightarrow \mathscr {L}(V_1^*,V_1)\) given by
It follows in particular that \({\mathcal {E}}_\lambda \) and \(D {\mathcal {E}}_\lambda \) are bounded on bounded subsets of \(V_1^*\), and that \(D{\mathcal {E}}_\lambda \) has linear growth. Moreover, from the equation it also follows that
Taking these remarks into account, Itô’s formula for \({\mathcal {E}}_\lambda (R_\varepsilon u_\lambda ^\sigma )\) yields, for every \(t\in [0,T]\),
where \((e_k)_k\) is a complete orthonormal system of U. Taking into account the Lipschitz-continuity of \(\pi \) and rearranging the terms, by the Young inequality we infer that, for every \(\eta >0\),
where the implicit constant is independent of \(\lambda \), \(\sigma \) and \(\varepsilon \). On the left hand side, a direct computation based on integration by parts and the definition of \(R_\varepsilon ^{-1}\) yields
Let us show how to control the stochastic integral. To this end, note that for every \(k\in \mathbb {N}\)
so that thanks to the Burkholder–Davis–Gundy, Poincaré and Young inequalities, we deduce that, for every \(\eta >0\),
Taking into account these last computations, it is clear that if B takes values in \(\mathscr {L}^2(U, V_{1,0}^*)\) as in (2.21) then we do not have the contribution given by \((w_\lambda )_D\) on the right-hand side. Consequently, choosing \(\eta \) sufficiently small, taking supremum in time, power \(\frac{q}{2}\) and expectations in Itô’s formula, rearranging the terms and recalling (3.13), since \(u_0\in L^q(\Omega ;V_1)\) and \({\widehat{\beta }}(u_0)\in L^{q/2}(\Omega ; L^1(D))\) we get
where again the implicit constant is independent of \(\lambda \), \(\sigma \) and \(\varepsilon \). Let us estimate now the last term according to the different assumptions of Theorem 2.10: we do not go through the details as the argument is similar to the one performed in [62, § 5]. Under assumption (2.22), we can write \(R_\varepsilon ^{-1}B=B^\varepsilon _1+B^\varepsilon _2\) for some \(B_1^\varepsilon \in L^\infty (\Omega \times (0,T); \mathscr {L}^2(U, H))\) and \(B_2^\varepsilon \in L^q(0,T; L^\infty (\Omega ; \mathscr {L}^2(U, V_1)))\). Hence, using the fact that \(V_2\hookrightarrow L^\infty (D)\) and that \(\beta '\) has quadratic growth, we get
while by the Hölder inequality and the fact that \(V_{\frac{N}{6}}\hookrightarrow L^3(D)\)
Otherwise, if (2.23) is in order, using the fact that \(V_s\hookrightarrow L^\infty (D)\) for \(s>\frac{N}{2}\) thanks to the Sobolev embeddings, by the growth assumption on \(\beta '\) we have that
Hence, it is clear that in both cases the terms on the right-hand side can be handled using the Gronwall lemma and the terms on the left-hand side. Finally, recalling the definition of \(\mathbf{w}^\sigma _\lambda \), by the growth assumption on \(\beta \) and the Lipschitz-continuity of \(\pi \) we have
Going back then to Itô’s inequality and using the Gronwall lemma, we deduce that there exists \(T_0\in (0,T]\) sufficiently small, independent of \(\lambda \), \(\sigma \) and \(\varepsilon \), such that
where \(C_\varepsilon \) is a positive constant, independent of \(\lambda \) and \(\sigma \), depending only on the norms of \(R_\varepsilon ^{-1}B\) in the spaces given by the assumptions (2.22) or (2.23).
Now, let us fix \(\varepsilon ,\lambda >0\): the only dependence on \(\sigma \) is contained in the last term on the right-hand side. In particular, we have
By the regularity of g we have that \(g^\sigma \rightarrow g\) in \(L^q(\Omega ;L^2(0,T; V_1))\), while the Lipschitz-continuity of \(\beta _\lambda \) and \(\pi \) imply that \(\mathbf{w}^\sigma _\lambda -w^\sigma _\lambda \rightarrow 0\) in \(L^q(\Omega ; L^2(0,T; H))\), as \(\sigma \searrow 0\). Furthermore since \(\lambda \) is fixed, it is not difficult to check that \(\beta _\lambda (u_\lambda ^\sigma )\rightarrow \beta _\lambda (u_\lambda )\) in \(L^q(\Omega ; L^2(0,T; V_1))\) provided that \(\beta _\lambda \in C^1_b(\mathbb {R})\): in general this is not granted by the definition of Yosida approximation. However, it can be obtained by a further regularization on the problem (for example considering a smoothed version of the Yosida approximation which preserves monotonicity). Since we are still arguing with \(\lambda \) fixed, a further approximation would not be restrictive, hence we omit it for brevity. A similar argument holds for the term in \(\pi \). Taking these remarks into account and letting \(\sigma \searrow 0\), we get by lower semicontinuity
with implicit constant independent of \(\lambda \) and \(\varepsilon \), and \(C_\varepsilon \) as before. Recalling that \(T_0\) is independent of both \(\lambda \) and \(\varepsilon \), by a classical patching argument we infer that
where \(M_\varepsilon >0\) only depends on the norms of \(R_\varepsilon ^{-1}B\) in the spaces given the respective assumptions in Theorem 2.10. Recalling that \(\left\| \cdot \right\| _{1}\) is an equivalent norm in \(V_1\), we deduce in particular that
Moreover, using the growth assumption on \(\beta \), we also deduce by comparison that
Completing now the proof of existence as in Sect. 3 taking into account the estimates above yields the desired regularity result.
In order to prove the result for the pure case, it is immediate to check that if \(\varepsilon =0\) then (2.20)–(2.23) imply that \(M_\varepsilon \) is uniformly bounded in \(\varepsilon \), so that we can conclude easily thanks to the convergence result in Theorem 2.6.
Finally, let us prove the last sentence of Theorem 2.10. By the results already proved, we know in particular that \(u\in L^\infty (0,T; V_1)\) \(\mathbb {P}\)-almost surely. Hence, if (2.22) is in order we have that \(\beta _\lambda (u)\in L^\infty (0,T; V_1)\) and
from which the Hölder inequality and the Sobolev embedding theorems yield
where the right-hand side is finite \(\mathbb {P}\)-almost surely. We deduce by Hölder inequality that the family \((\nabla \beta _\lambda (u(\omega )))_\lambda \) is uniformly bounded in \(L^{q/3}(\Omega ; L^2(0,T; H))\), which implies that \(\nabla \xi \in L^{q/3}(\Omega ; L^2(0,T; H))\), so that \(\xi \in L^{q/3}(\Omega ; L^2(0,T; V_1))\) since \(\frac{q}{2}>\frac{q}{3}\). Furthermore, if \(\varepsilon =0\), we have already proved that \(w\in L^{q/3}(\Omega ; L^2(0,T; V_1))\), and \(g\in L^{q/3}(\Omega ; L^2(0,T; V_1))\) as a consequence of assumption (2.17). In addition, since \(\pi \) is Lipschitz-continuous we also have that \(\pi (u)\in L^{q/3}(\Omega ; L^2(0,T; V_1))\). Hence, by comparison in the equation we infer that \(-\Delta u \in L^{q/3}(\Omega ; L^2(0,T; V_1))\), from which the thesis follows by elliptic regularity.
References
Antonopoulou, D.C., Karali, G., Millet, A.: Existence and regularity of solution for a stochastic Cahn-Hilliard/Allen-Cahn equation with unbounded noise diffusion. J. Differ. Equ. 260(3), 2383–2417 (2016)
Barbu, V., Da Prato, G., Röckner, M.: Existence of strong solutions for stochastic porous media equation under general monotonicity conditions. Ann. Probab. 37(2), 428–452 (2009)
Bauzet, C., Bonetti, E., Bonfanti, G., Lebon, F., Vallet, G.: A global existence and uniqueness result for a stochastic Allen-Cahn equation with constraint. Math. Methods Appl. Sci. 40(14), 5241–5261 (2017)
Bonetti, E., Colli, P., Scarpa, L., Tomassetti, G.: A doubly nonlinear Cahn-Hilliard system with nonlinear viscosity. Commun. Pure Appl. Anal. 17(3), 1001–1022 (2018)
Brézis, H.: Monotonicity methods in Hilbert spaces and some applications to nonlinear partial differential equations. In: Contributions to nonlinear functional analysis (Proc. Sympos., Math. Res. Center, Univ. Wisconsin, Madison, Wis., 1971), pp. 101–156. Academic Press, New York (1971)
Cahn, J.W., Hilliard, J.E.: Free energy of a nonuniform system. i. interfacial free energy. J. Chem. Phys. 28(2), 258–267 (1958)
Cherfils, L., Petcu, M.: A numerical analysis of the Cahn-Hilliard equation with non-permeable walls. Numer. Math. 128(3), 517–549 (2014)
Cherfils, L., Miranville, A., Zelik, S.: The Cahn-Hilliard equation with logarithmic potentials. Milan J. Math. 79(2), 561–596 (2011)
Cherfils, L., Gatti, S., Miranville, A.: A variational approach to a Cahn-Hilliard model in a domain with nonpermeable walls. J. Math. Sci. (N.Y.) 189(4), 604–636 (2013). (Problems in mathematical analysis. No. 69)
Colli, P., Fukao, T.: Cahn-Hilliard equation with dynamic boundary conditions and mass constraint on the boundary. J. Math. Anal. Appl. 429(2), 1190–1213 (2015)
Colli, P., Fukao, T.: Equation and dynamic boundary condition of Cahn-Hilliard type with singular potentials. Nonlinear Anal. 127, 413–433 (2015)
Colli, P., Fukao, T.: Nonlinear diffusion equations as asymptotic limits of Cahn-Hilliard systems. J. Differ. Equ. 260(9), 6930–6959 (2016)
Colli, P., Scarpa, L.: From the viscous Cahn-Hilliard equation to a regularized forward-backward parabolic equation. Asymptot. Anal. 99(3–4), 183–205 (2016)
Colli, P., Gilardi, G., Sprekels, J.: On the Cahn-Hilliard equation with dynamic boundary conditions and a dominating boundary potential. J. Math. Anal. Appl. 419(2), 972–994 (2014)
Colli, P., Farshbaf-Shaker, M.H., Gilardi, G., Sprekels, J.: Optimal boundary control of a viscous Cahn-Hilliard system with dynamic boundary condition and double obstacle potentials. SIAM J. Control Optim. 53(4), 2696–2721 (2015)
Colli, P., Gilardi, G., Hilhorst, D.: On a Cahn-Hilliard type phase field system related to tumor growth. Discret. Contin. Dyn. Syst. 35(6), 2423–2442 (2015)
Colli, P., Gilardi, G., Rocca, E., Sprekels, J.: Vanishing viscosities and error estimate for a Cahn-Hilliard type phase field system related to tumor growth. Nonlinear Anal. Real World Appl. 26, 93–108 (2015)
Colli, P., Gilardi, G., Sprekels, J.: A boundary control problem for the pure Cahn-Hilliard equation with dynamic boundary conditions. Adv. Nonlinear Anal. 4(4), 311–325 (2015)
Colli, P., Gilardi, G., Sprekels, J.: A boundary control problem for the viscous Cahn-Hilliard equation with dynamic boundary conditions. Appl. Math. Optim. 73(2), 195–225 (2016)
Colli, P., Gilardi, G., Rocca, E., Sprekels, J.: Asymptotic analyses and error estimates for a Cahn-Hilliard type phase field system modelling tumor growth. Discret. Contin. Dyn. Syst. Ser. S 10(1), 37–54 (2017)
Cook, H.: Brownian motion in spinodal decomposition. Acta Metall. 18(3), 297–306 (1970)
Cornalba, F.: A nonlocal stochastic Cahn-Hilliard equation. Nonlinear Anal. 140, 38–60 (2016)
Cristini, V., Li, X., Lowengrub, J.S., Wise, S.M.: Nonlinear simulations of solid tumor growth using a mixture model: invasion and branching. J. Math. Biol. 58(4), 723 (2008)
Da Prato, G., Debussche, A.: Stochastic Cahn-Hilliard equation. Nonlinear Anal. 26(2), 241–263 (1996)
Debussche, A., Goudenège, L.: Stochastic Cahn-Hilliard equation with double singular nonlinearities and two reflections. SIAM J. Math. Anal. 43(3), 1473–1494 (2011)
Debussche, A., Zambotti, L.: Conservative stochastic Cahn-Hilliard equation with reflection. Ann. Probab. 35(5), 1706–1739 (2007)
Elezović, N., Mikelić, A.: On the stochastic Cahn-Hilliard equation. Nonlinear Anal. 16(12), 1169–1200 (1991)
Elliott, C.M., Songmu, Z.: On the Cahn-Hilliard equation. Arch. Ration. Mech. Anal. 96(4), 339–357 (1986)
Elliott, C.M., Stuart, A.M.: Viscous Cahn-Hilliard equation. II. Analysis. J. Differ. Equ. 128(2), 387–414 (1996)
Feireisl, E., Petcu, M.: A diffuse interface model of a two-phase flow with thermal fluctuations. Appl. Math. Optim. (2019)
Feireisl, E., Petcu, M.: Stability of strong solutions for a model of incompressible two-phase flow under thermal fluctuations. J. Differ. Equ. 267(3), 1836–1858 (2019)
Frigeri, S., Grasselli, M., Rocca, E.: On a diffuse interface model of tumour growth. Eur. J. Appl. Math. 26(2), 215–243 (2015)
Garcke, H., Lam, K.F.: Analysis of a Cahn-Hilliard system with non-zero Dirichlet conditions modeling tumor growth with chemotaxis. Discret. Contin. Dyn. Syst. 37(8), 4277–4308 (2017)
Garcke, H., Lam, K.F.: Well-posedness of a Cahn-Hilliard system modelling tumour growth with chemotaxis and active transport. Eur. J. Appl. Math. 28(2), 284–316 (2017)
Garcke, H., Lam, K.F., Sitka, E., Styles, V.: A Cahn-Hilliard-Darcy model for tumour growth with chemotaxis and active transport. Math. Models Methods Appl. Sci. 26(06), 1095–1148 (2016)
Garcke, H., Lam, K.F., Rocca, E.: Optimal control of treatment time in a diffuse interface model of tumor growth. Appl. Math. Optim. 78, 49–544 (2017)
Gilardi, G., Miranville, A., Schimperna, G.: On the Cahn-Hilliard equation with irregular potentials and dynamic boundary conditions. Commun. Pure Appl. Anal. 8(3), 881–912 (2009)
Gilardi, G., Miranville, A., Schimperna, G.: Long time behavior of the Cahn-Hilliard equation with irregular potentials and dynamic boundary conditions. Chin. Ann. Math. Ser. B 31(5), 679–712 (2010)
Goudenège, L.: Stochastic Cahn-Hilliard equation with singular nonlinearity and reflection. Stoch. Process. Appl. 119(10), 3516–3548 (2009)
Haase, M.: Convexity inequalities for positive operators. Positivity 11(1), 57–68 (2007)
Hao, C., Wang, G.: Well-posedness for the stochastic viscous Cahn-Hilliard equation. J. Nonlinear Convex Anal. 18(12), 2219–2228 (2017)
Hawkins-Daarud, A., van der Zee, K .G., Oden., J Tinsley: Numerical simulation of a thermodynamically consistent four-species tumor growth model. Int. J. Numer. Methods Biomed. Eng. 28(1), 3–24 (2012)
Hawkins-Daarud, A., Prudhomme, S., van der Zee, K.G., Oden, J.T.: Bayesian calibration, validation, and uncertainty quantification of diffuse interface models of tumor growth. J. Math. Biol. 67(6), 1457–1485 (2013)
Hintermüller, M., Wegner, D.: Distributed optimal control of the Cahn-Hilliard system including the case of a double-obstacle homogeneous free energy density. SIAM J. Control Optim. 50(1), 388–418 (2012)
Ju, X., Wang, H., Li, D., Duan, J.: Global mild solutions and attractors for stochastic viscous Cahn-Hilliard equation. Abstr. Appl. Anal. pages Art. ID 670786, 22 (2011)
Kardestuncer, H., Norrie, D.H. (eds.): Chapters 1–3 in Finite Element Handbook. McGraw-Hill Book Co., New York (1987)
Krylov, N.V., Rozovskiĭ, B.L.: Stochastic evolution equations. In: Current Problems in Mathematics, vol. 14 (Russian)
Lee, D., Huh, J.-Y., Jeong, D., Shin, J., Yun, A., Kim, J.: Physical, mathematical, and numerical derivations of the Cahn-Hilliard equation. Comput. Mater. Sci. 81, 216–225 (2014)
Marinelli, C., Scarpa, L.: Refined existence and regularity results for a class of semilinear dissipative SPDEs. ArXiv e-prints (2017)
Marinelli, C., Scarpa, L.: Ergodicity and kolmogorov equations for dissipative spdes with singular drift: a variational approach. Potential Anal. arXiv:1710.05612
Marinelli, C., Scarpa, L.: A note on doubly nonlinear SPDEs with singular drift in divergence form. Atti Accad. Naz. Lincei Rend. Lincei Mat. Appl. 29(4), 619–633 (2018)
Marinelli, C., Scarpa, L.: On the well-posedness of SPDEs with singular drift in divergence form. In: Eberle, A., Grothaus, M., Hoh, W., Kassmann, M., Stannat, W., Trutnau, G. (eds.) Stochastic Partial Differential Equations and Related Fields, pp. 225–235. Springer, Cham (2018)
Marinelli, C., Scarpa, L.: Strong solutions to SPDEs with monotone drift in divergence form. Stoch. Partial Differ. Equ. Anal. Comput. 6(3), 364–396 (2018)
Marinelli, C., Scarpa, L.: A variational approach to dissipative SPDEs with singular drift. Ann. Probab. 46(3), 1455–1497 (2018)
Miranville, A., Schimperna, G.: On a doubly nonlinear Cahn-Hilliard-Gurtin system. Discret. Contin. Dyn. Syst. Ser. B 14(2), 675–697 (2010)
Novick-Cohen, A.: On the viscous Cahn-Hilliard equation. In: Material instabilities in continuum mechanics (Edinburgh, 1985–1986), Oxford Sci. Publ., pp. 329–342. Oxford Univ. Press, New York (1988)
Oden, J.T., Hawkins, A., Prudhomme, S.: General diffuse-interface theories and an approach to predictive tumor growth modeling. Math. Model. Methods Appl. Sci. 20(03), 477–517 (2010)
Orrieri, C., Scarpa, L.: Singular stochastic Allen-Cahn equations with dynamic boundary conditions. J. Differ. Equ. 266(8), 4624–4667 (2019)
Pardoux, E.: Equations aux derivées partielles stochastiques nonlinéaires monotones. PhD thesis, Université Paris XI, (1975)
Prévôt, C., Röckner, M.: A Concise Course on Stochastic Partial Differential Equations. Lecture Notes in Mathematics, vol. 1905. Springer, Berlin (2007)
Scarpa, L.: Well-posedness for a class of doubly nonlinear stochastic PDEs of divergence type. J. Differ. Equ. 263(4), 2113–2156 (2017)
Scarpa, L.: On the stochastic Cahn-Hilliard equation with a singular double-well potential. Nonlinear Anal. 171, 102–133 (2018)
Scarpa, L.: Existence and uniqueness of solutions to singular Cahn-Hilliard equations with nonlinear viscosity terms and dynamic boundary conditions. J. Math. Anal. Appl. 469(2), 730–764 (2019)
Simon, J.: Compact sets in the space \(L^p(0, T;B)\). Ann. Mat. Pura Appl. 4(146), 65–96 (1987)
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Scarpa, L. The Stochastic Viscous Cahn–Hilliard Equation: Well-Posedness, Regularity and Vanishing Viscosity Limit. Appl Math Optim 84, 487–533 (2021). https://doi.org/10.1007/s00245-020-09652-9
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DOI: https://doi.org/10.1007/s00245-020-09652-9
Keywords
- Stochastic viscous Cahn–Hilliard equation
- Singular potential
- Well-posedness
- Regularity
- Vanishing viscosity
- Variational approach