Well-Posed Final Value Problems and Duhamel's Formula for Coercive Lax--Milgram Operators
Jon Johnsen

TL;DR
This paper establishes well-posedness for parabolic final value problems involving coercive Lax--Milgram operators, extending classical results to unbounded semigroups and providing a Duhamel formula within this framework.
Contribution
It introduces a novel approach to well-posedness for coercive Lax--Milgram operators using an isomorphism between data and solution spaces, extending invertibility to unbounded semigroups.
Findings
Proves well-posedness for a large class of final value problems.
Extends invertibility of analytic semigroups to unbounded semigroups.
Derives a Duhamel formula for the set-up.
Abstract
This paper treats parabolic final value problems generated by coercive Lax--Milgram operators, and well-posedness is proved for this large class. The result is obtained by means of an isomorphism between Hilbert spaces containing the data and solutions. Like for elliptic generators, the data space is the graph normed domain of an unbounded operator that maps final states to the corresponding initial states, and the resulting compatibility condition extends to the coercive context. Lax--Milgram operators in vector distribution spaces is the main framework, but the crucial tool that analytic semigroups always are invertible in the class of closed operators is extended to unbounded semigroups, and this is shown to yield a Duhamel formula for the Cauchy problems in the set-up. The final value heat conduction problem with the homogeneous Neumann boundary condition on a smooth open set is…
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Well-Posed Final Value Problems and Duhamel’s Formula for Coercive Lax–Milgram Operators
Jon Johnsen
Department of Mathematics, Aalborg University, Skjernvej 7A, DK-9220 Denmark
Abstract.
This paper treats parabolic final value problems generated by coercive Lax–Milgram operators, and well-posedness is proved for this large class. The result is obtained by means of an isomorphism between Hilbert spaces containing the data and solutions. Like for elliptic generators, the data space is the graph normed domain of an unbounded operator that maps final states to the corresponding initial states, and the resulting compatibility condition extends to the coercive context. Lax–Milgram operators in vector distribution spaces is the main framework, but the crucial tool that analytic semigroups always are invertible in the class of closed operators is extended to unbounded semigroups, and this is shown to yield a Duhamel formula for the Cauchy problems in the set-up. The final value heat conduction problem with the homogeneous Neumann boundary condition on a smooth open set is also proved to be well posed in the sense of Hadamard.
Key words and phrases:
Duhamel formula, coercive operator, final value data, Neumann heat problem, well-posed
2010 Mathematics Subject Classification:
35A01, 47D06
Appeared in Electronic Research Archives, vol. 27 (2019), 20--36; doi:10.3934/era2019008
1. Introduction
Well-posedness of final value problems for a large class of parabolic differential equations was recently obtained in a joint work of the author and given an ample description for a broad audience in [5], after the announcement in [4]. The present paper substantiates the indications made in the concise review [21], namely, that the abstract parts in [5] extend from -elliptic Lax–Milgram operators to those that are merely -coercive—despite that such may be non-injective.
As an application, the final value heat conduction problem with the homogeneous Neumann condition is shown to be well-posed.
The basic analysis is made for a Lax–Milgram operator defined in from a -coercive sesquilinear form in a Gelfand triple, i.e., three separable, densely injected Hilbert spaces having the norms , and , respectively. Hereby is the form domain of ; and the antidual of . Specifically there are constants and such that all satisfy and
[TABLE]
In fact, consists of those for which for some holds for all , and ; hereby denotes the inner product in . There is also an extension given by for . This is uniquely determined as is dense in .
Both and are referred to as -elliptic if the above holds for ; then is a bijection. One may consult the book of Grubb [12] or that of Helffer [14], or [5], for more details on the set-up and basic properties of the unbounded, but closed operator in . Especially is self-adjoint in if and only if , which is not assumed; may also be nonnormal in general.
In the framework of such a triple , the general final value problem is the following: for given data and , determine the such that
[TABLE]
By definition of Schwartz’ vector distribution space as the space of continuous linear maps , cf. [28], the above equation means that for every scalar test function the identity holds in .
As is well known, a wealth of parabolic Cauchy problems with homogeneous boundary conditions have been treated via triples and the set-up in (2); cf. the work of Lions and Magenes [24], Tanabe [30], Temam [31], Amann [2] etc.
The theoretical analysis made in [4, 5, 21] shows that, in the -elliptic case, the problem in (2) is well posed, i.e., it has existence, uniqueness and stability of a solution for given data , in certain Hilbertable spaces , that were described explicitly. Hereby the data space is defined in terms of a particular compatibility condition, which was introduced for the purpose in [4, 5]. More precisely, there is even a linear homeomorphism , which yields well-posedness in a strong form.
This has seemingly closed a gap in the theory, which had remained since the 1950’s, even though the well-posedness is decisive for the interpretation and accuracy of numerical schemes for the problem (the work of John [19] was pioneering, but also Eldén [8] could be mentioned). In rough terms, the results are derived from a useful structure on the reachable set for a general class of parabolic differential equations.
The main example treated in [4, 5] is the heat conduction problem of characterising the that in a -smooth bounded open set with boundary fulfil the equations (for ),
[TABLE]
An area of interest of this could be a nuclear power plant hit by a power failure at : after power is regained at , and the reactor temperatures are measured, a calculation backwards in time could possibly settle whether at some the temperatures could cause damage to the fuel rods.
However, the Dirichlet condition at the boundary is of limited physical importance, so an extension to, e.g., the Neumann condition, which represents controlled heat flux at , makes it natural to work out an extension to -coercive Lax–Milgram operators .
In this connection it should be noted that when is -coercive (that is, satisfies (1) only for some ), it is possible that , the spectrum of , for example because is an eigenvalue of . In fact, this is the case for the Neumann realisation , which has the space of constant functions as the null space. Well-posedness is obtained for the heat problem (3) with a replacement of the Dirichlet condition by the homogeneous Neumann condition in Section 4 below.
At first glance, it may seem surprising that the possible non-injectivity of the coercive operator is inconsequential for the well-posedness of the final value problem (2). In particular this means that the backward uniqueness— in implies in for —of the equation will hold regardless of whether is injective or not. This can be seen from the extensions of the abstract theory given below; in particular when the results are applied in Section 4 to the case .
The point of departure is to make a comparison of (2) with the corresponding Cauchy problem for the equation . For this it is classical to seek solutions in the Banach space
[TABLE]
In fact, the following result is essentially known from the work of Lions and Magenes [24]:
Proposition 1**.**
Let be a separable Hilbert space with algebraically, topologically and densely, and let denote the Lax–Milgram operator induced by a -coercive, bounded sesquilinear form on , as well as its extension . When and are given, then there is a uniquely determined solution belonging to , cf. (4), of the Cauchy problem
[TABLE]
The solution operator is continuous , and problem (5) is well-posed.
Remarks on the classical reduction from the -coercive case to the elliptic one will follow in Section 3. The stated continuity of the solution operator is well known to the experts. But for the reader’s convenience, in Proposition 7 below, the continuity is shown by explicit estimates using Grönwall’s lemma; these may be of independent interest.
Whilst the below expression for the solution hardly is surprising at all, it has seemingly not been obtained hitherto in the present context of -coercive Lax–Milgram operators and general triples :
Proposition 2**.**
The unique solution in provided by Proposition 1 is given by Duhamel’s formula,
[TABLE]
Here each of the three terms belongs to .
As shown in Section 3 below, it suffices for (6) to reinforce the classical integration factor technique by injectivity of the semigroup .
In fact, it is exploited in (6) and throughout that generates an analytic semigroup in . As a consequence of the analyticity, the family of operators was shown in [5] to consist of injections on in case is -elliptic. This extends to general -coercive , as accounted for in Proposition 5 below. Hence also in the present paper has the inverse for .
For , the Duhamel formula (6) now obviously yields a bijection between the initial and terminal states (for fixed ), as one can solve for by means of the inverse . In particular backwards uniqueness of the solutions to holds in the large class .
Returning to the final value problem (2) it would be natural to seek solutions in the same space . This turns out to be possible only when the data are subjected to substantial further conditions.
To formulate these, it is noted that the above inverse enters the theory through its domain, which in the algebraic sense simply is a range, namely ; but this domain has the structural advantage of being a Hilbert space under the graph norm .
For the domains have a decisive role in the well-posedness result below, where condition (9) is a fundamental clarification for the final value problem in (2) and the parabolic problems it represents.
Another ingredient in (9) is the full yield of the source term , namely
[TABLE]
Hereby it is used that extends to an analytic semigroup in , as the extension is an unbounded operator in the Hilbertable space satisfying the necessary estimates (cf. Remark 4; and also [5, Lem. 5] for the extension). So is a priori a vector in , but in fact lies in as Proposition 2 shows it equals the final state of a solution in of a Cauchy problem having .
These remarks on make it clear that in the following main result of the paper—which relaxes the assumption of -ellipticity in [4, 5] to -coercivity—the difference in (9) is a member of :
Theorem 1**.**
Let be a -coercive Lax–Milgram operator defined from a triple as above. Then the abstract final value problem (2) has a solution belonging the space in (4), if and only if the data belong to the subspace
[TABLE]
defined by the condition
[TABLE]
In the affirmative case, the solution is uniquely determined in and
[TABLE]
whence the solution operator is continuous . Moreover,
[TABLE]
where all terms belong to as functions of , and the difference in (9) equals in .
The norm on the data space in (10) is seen at once to be the graph norm of the composite map
[TABLE]
given by and .
In fact, the solvability criterion (9) means that must be defined at , so the data space is its domain. Being an inverse, is a closed operator in , and so is ; hence is complete. Now, since in (10) the Banach space is Hilbertable, so is .
Thus the unbounded operator is a key ingredient in the rigorous treatment of the final value problem (2). In control theoretic terms, the role of is to provide the unique initial state given by
[TABLE]
which is steered by to the final state at time ; cf. the Duhamel formula (6).
Criterion (9) is a generalised compatibility condition on the data ; such conditions have long been known in the theory of parabolic problems, cf. Remark 7. The presence of and the integral over makes (9) non-local in both space and time. This aspect is further complicated by the reference to , which for larger final times typically gives increasingly stricter conditions:
Proposition 3**.**
If the spectrum of is not contained in the strip \{\,z\in{\mathbb{C}}\bigm{|}-k\leq\Re z\leq k\,\}, whereby is the constant from (1), then the domains form a strictly descending chain, that is,
[TABLE]
This results from the injectivity of via well-known facts for semigroups reviewed in [5, Thm. 11] (with reference to [26]). In fact, the arguments given for in [5, Prop. 11] apply mutatis mutandis.
Now, (6) also shows that has two radically different contributions, even if has nice properties. First, for the integral equals , which can be anywhere in . Indeed, is a continuous surjection . This was shown for via the Closed Range Theorem in [5, Prop. 5], and for surjectivity follows from this case as in (7), whereby is -elliptic and is a bijection on .
Secondly, solves , and for and -elliptic it is a precise property in non-selfadjoint dynamics that the “height” is
[TABLE]
Whilst this holds if is self-adjoint or normal, it was emphasized in [5] that it suffices that is just hyponormal (i.e., and for , following Janas [18]). Recently this was followed up by the author in [20], where the stronger logarithmic convexity of was proved equivalent to the formally weaker property of that, for ,
[TABLE]
For -coercive only the strict decrease may need to be relinquished. Indeed, the strict positivity follows by the injectivity of in Proposition 5 below. Moreover, the characterisation in [20, Lem. 2.2] of the log-convex -functions on as the solutions of the differential inequality and the resulting criterion for in (15) apply verbatim to the coercive case; hereby the differential calculus in Banach spaces is exploited in a classical derivation of the formulae for ,
[TABLE]
But it is due to the strict positivity for in the denominators that the expressions make sense, so injectivity of also enters crucially at this point. Similarly the singularity of at the origin poses no problems for the mere differentiation of . Therefore it is likely that the natural formulas for , have not been rigorously proved before [21]. These remarks also shed light on the usefulness of Proposition 5 below.
However, the stiffness intrinsic to strict convexity, hence to log-convexity, corresponds well with the fact that in any case is confined to a dense, but very small space, as by the analyticity
[TABLE]
For , the possible will hence be a sum of some arbitrary and a stiff term . Thus can be prescribed in the affine space . As any will shift in an arbitrary direction, can be expected anywhere in (unless is known). So neither (18) nor can be expected to hold if —not even if is much smaller than . Hence it seems best for final value problems to consider inhomogeneous problems from the outset.
Remark 1*.*
To give some backgound, two classical observations for the homogeneous case , in (3) are recalled. First there is the smoothing effect for of parabolic Cauchy problems, which means that whenever . (Rauch [27, Thm. 4.3.1] has a version for ; Evans [9, Thm. 7.1.7] gives the stronger result when , and fulfill the classical compatibility conditions at —which for , gives the property on for any , hence on ). Therefore ; whence (3) with , cannot be solved if is prescribed arbitrarily in . But this just indicates an asymmetry in the properties of the initial and final value problems.
Secondly, there is a phenomenon of -instability in case , in (3), which perhaps was first described by Miranker [25]. The instability is found via the Dirichlet realization of the Laplacian, , and its -orthonormal basis of eigenfunctions associated to the usual ordering of its eigenvalues , which via Weyl’s law for the counting function, cf. [6, Ch. 6.4], gives
[TABLE]
This basis gives rise to a sequence of final value data lying on the unit sphere in as for . But the corresponding solutions to , i.e. , have initial states with -norms that because of (19) grow rapidly with the index ,
[TABLE]
This -instability cannot be removed, of course, but it only indicates that the -norm is an insensitive choice for problem (3). The task is hence to obtain a norm on giving better control over the backward calculations of —for the inhomogeneous heat problem (3), an account of this was given in [5].
Remark 2*.*
Almog, Grebenkov, Helffer, Henry [1, 10, 11] studied the complex Airy operator recently via triples , leading to Dirichlet, Neumann, Robin and transmission boundary conditions, in bounded and unbounded regions. Theorem 1 is expected to apply to final value problems for those of their realisations that satisfy the coercivity condition in (1). However, has empty spectrum on , cf. the fundamental paper of Herbst [15], so it remains to be seen for which of the regions in [1, 10, 11] there is a strictly descending chain of domains as in (14).
2. Preliminaries: Injectivity of Analytic Semigroups
As indicated in the introduction, it is central to the analysis of final value problems that an analytic semigroup of operators, like , always consists of injections. This shows up both at the technical and conceptual level, that is, both in the proofs and in the objects that enter the theorem.
A few aspects of semigroup theory in a complex Banach space is therefore recalled. Besides classical references by Davies [7], Pazy [26], Tanabe [30] or Yosida [32], a more recent account is given in [3].
The generator is , where belongs to the domain when the limit exists. is a densely defined, closed linear operator in that for some , satisfies the resolvent estimates for , .
The corresponding -semigroup of operators is of type : it fulfils that for , and for ; whilst
[TABLE]
Indeed, the Laplace transformation gives a bijection of the semigroups of type onto (the resolvents of) the stated class of generators.
To elucidate the role of injectivity, recall that if is analytic, , is uniquely solved by for every . Here injectivity of is equivalent to the important geometric property that the trajectories of two solutions and of have no confluence point in for .
Nevertheless, the literature seems to have focused on examples of semigroups with non-invertibility of , like [26, Ex. 2.2.1]; these necessarily concern non-analytic cases. The well-known result below gives a criterion for to generate a -semigroup that is defined and analytic for in the open sector
[TABLE]
It is formulated in terms of the spectral sector
[TABLE]
Proposition 4**.**
If generates a -semigroup of type and , the following properties are equivalent for each :
- (i)
The resolvent set contains and
[TABLE]
- (ii)
The semigroup extends to an analytic semigroup defined for with
[TABLE]
In the affirmative case, is differentiable in for with derivative , and for every such that one has
[TABLE]
whereby denotes the spectral abscissa of (here , as ).
In case , the equivalence is just a review of the main parts of Theorem 2.5.2 in [26]. For general , one can reduce to this case, since yields the operator identity , where is of type for some . Indeed, the right-hand side is easily seen to be a -semigroup, which since has as its generator, so the identity results from the bijectiveness of the Laplace transform. In this way, (i)(ii) follows straightforwardly from the case , using for both implications that holds in by unique analytic extension.
Since implies , the above translation method gives , where is of type whenever . This yields the first part of (26), and the second now follows from this and the case by means of the splitting for .
The reason for stating Proposition 4 for general type semigroups is that it shows explicitly that cases with only have other estimates on or in the closed subsectors —but the mere analyticity in is unaffected by the translation by . Hence one has the following improved version of [5, Prop. 1]:
Proposition 5**.**
If a -semigroup of type on a complex Banach space has an analytic extension to for some , then is injective for every .
Proof.
Let hold for some and . Analyticity of in carries over by the differential calculus in Banach spaces to the map . So for in a suitable open ball , a Taylor expansion and the identity for analytic semigroups (cf. [26, Lem. 2.4.2]) give
[TABLE]
Hence on by unique analytic extension. Now, as is strongly continuous at , we have . Thus the null space of is trivial. ∎
Remark 3*.*
The injectivity in Proposition 5 was claimed in [29] for , and a Hilbert space (but not quite obtained, as noted in [5, Rem. 1]; cf. the details in Lemma 3.1 and Remark 3 in [20]). A local version for the Laplacian on was given by Rauch [27, Cor. 4.3.9].
As a consequence of the above injectivity, for an analytic semigroup we may consider its inverse that, consistently with the case in which forms a group in , may be denoted for by . Clearly maps bijectively onto , and it is an unbounded, but closed operator in .
Specialising to a Hilbert space , then also is analytic, so holds for its null space by Proposition 5; whence is dense in . Some further basic properties are:
Proposition 6**.**
[5, Prop. 2]** The above inverses form a semigroup of unbounded operators in ,
[TABLE]
This extends to , whereby may be unbounded for . Moreover, as unbounded operators the commute with , that is, for , and have a descending chain of domains, for .
Remark 4*.*
The above domains serve as basic structures for the final value problem (3). They apply for that generates an analytic semigroup in defined in for . Indeed, this was shown in [5, Lem. 4] with a concise argument using -ellipticity of ; the -coercive case follows easily from this via the formula that results for from the translation trick after Proposition 4; and then it defines by the right-hand side for every . (A rather more involved argument was given in [26, Thm. 7.2.7] in a context of uniformly strongly elliptic differential operators.)
3. Proof of Theorem 1
To clarify a redundancy in the set-up, it is remarked here that in Proposition 1 the solution space is a Banach space, which can have its norm in (4) rewritten in the following form, using the Sobolev space H^{1}(0,T;V^{*})=\bigl{\{}\,u\in L_{2}(0,T;V^{*})\bigm{|}\partial_{t}u\in L_{2}(0,T;V^{*})\,\bigr{\}},
[TABLE]
Here there is a well-known inclusion and an associated Sobolev inequality for vector functions ([5] has an elementary proof)
[TABLE]
Hence one can safely omit the space in (4) and remove from . Similarly is redundant in (4) because , so an equivalent norm on is given by
[TABLE]
Thus is more precisely a Hilbertable space, as is so. But the form given in (4) is preferred in order to emphasize the properties of the solutions.
As a note on the equation with , the continuous function fulfils for a.e. , so the extension applies for a.e. . Hence belongs to .
3.1. Concerning Proposition 1
The existence and uniqueness statements in Proposition 1 are essentially special cases of the classical theory of Lions and Magenes, cf. [24, Sect. 3.4.4] on -dependent -elliptic forms . Indeed, because of the fixed final time , their indicated extension to -coercive forms works well here: since and are all bijections on and , respectively, the auxiliary problem , has a solution according to the statement for the -elliptic operator in [24, Sect. 3.4.4], when is the coercivity constant in (1); and since multiplication by the scalar commutes with for each , it follows from the Leibniz rule in that the function is in and satisfies
[TABLE]
Moreover, the uniqueness of a solution follows from that of , for if , , then it is seen at once that solves , ; so that , hence .
In the -elliptic case, the well-posedness in Proposition 1 is a known corollary to the proofs in [24]. For coercive , the above exponential factors should also be handled, which can be done explicitly using
Lemma 1** (Grönwall).**
When , and are positive Borel functions on , and is increasing, then validity on of the first of the following inequalities implies that of the second:
[TABLE]
The reader is referred to the proof of Lemma 6.3.6 in [17], which actually covers the slightly sharper statement above. Using this, one finds in a classical way a detailed estimate on each subinterval :
Proposition 7**.**
The unique solution of (5), cf. Proposition 1, fulfils in terms of the boundedness and coercivity constants , and of that for ,
[TABLE]
For , this entails boundedness of the solution operator .
Proof.
As , while and and hence also belong to the dual space , one has in the identity
[TABLE]
Here a classical regularisation yields , cf. [31, Lem. III.1.2] or [5, Lem. 2], so by Young’s inequality and the -coercivity,
[TABLE]
Integration of this yields, since and are in ,
[TABLE]
Ignoring the second term on the left-hand side, it follows from Lemma 1 that, for ,
[TABLE]
and since the right-hand side is increasing, one even has
[TABLE]
In addition it follows in a crude way, from (37) and an integrated version of (38), that
[TABLE]
Moreover, as solves (5), it is clear that , and since holds for the norm in , the above estimates entail
[TABLE]
Finally the stated estimate (34) follows from (39), (40) and (41). ∎
3.2. On the proof of the Duhamel formula
As a preparation, a small technical result is recalled from Proposition 3 in [5], where a detailed proof can be found:
Lemma 2**.**
When generates an analytic semigroup on the complex Banach space and , then the Leibniz rule
[TABLE]
is valid in .
In Proposition 2, equation (6) is of course just the Duhamel formula from analytic semigroup theory. However, since also contains non-classical solutions, (6) requires a proof in the present context—but as noted, it suffices just to reinforce the classical argument by the injectivity of in Proposition 5:
Proof of Proposition 2.
To address the last statement first, once (6) has been shown, Proposition 1 yields for . For general one has , so the last term containing also belongs to .
To obtain (6) in the above set-up, note that all terms in are in . Therefore applies for a.e. to both sides as an integration factor, so as an identity in ,
[TABLE]
Indeed, on the left-hand side is in and its derivative in follows the Leibniz rule in Lemma 2, since as a member of .
As , it is seen in the above that and both belong to . So when the Fundamental Theorem for vector functions (cf. [31, Lem. III.1.1], or [5, Lem. 1]) is applied and followed by use of the semigroup property and a commutation of with the integral, using Bochner’s identity, cf. Remark 5 below, one finds that
[TABLE]
Since is linear and injective, cf. Proposition 5, equation (6) now results at once. ∎
Remark 5*.*
It is recalled that for , where is a Banach space, it is a basic property that for every functional in the dual space , one has Bochner’s identity: .
3.3. Concerning Theorem 1
As all terms in (6) are in , it is safe to evaluate at , which in view of (7) gives that . This is the flow map
[TABLE]
Owing to the injectivity of once again, and that Duhamel’s formula implies , which clearly belongs to , this flow is inverted by
[TABLE]
In other words, not only are the solutions in to parametrised by the initial states in (for fixed ) according to Proposition 1, but also the final states are parametrised by the . Departing from this observation, one may give an intuitive
Proof of Theorem 1.
If (2) is solved by , then is reached from the unique initial state in (46). But the argument for (46) showed that , so (9) is necessary.
Given data that fulfill (9), then is a well-defined vector in , so Proposition 1 yields a function solving and . By the flow (45), this has final state , hence satisfies both equations in (2). Thus (9) suffices for solvability.
In the affirmative case, (11) results for any solution by inserting formula (46) for into (6). Uniqueness of in is seen from the right-hand side of (11), where all terms depend only on the given , , and . That each term in (11) is a function belonging to was seen in Proposition 2.
Moreover, the solution can be estimated in by substituting the expression (46) for into the inequality in Proposition 7 for . For the norm in (31) this gives
[TABLE]
Here one may add on the right-hand side to arrive at the expression for in Theorem 1. ∎
Remark 6*.*
It is easy to see from the definitions and proofs that is a bounded operator . The statement in Theorem 1 means that the solution operator (is well defined and) satisfies , but by the uniqueness also holds. Hence is a linear homeomorphism .
4. The heat problem with the Neumann condition
In the sequel stands for a smooth, open bounded set in , as described in [12, App. C]. In particular is locally on one side of its boundary . For such , the problem is to characterise the satisfying
[TABLE]
While , the Neumann trace on is written in the operator notation , whereby is the outward pointing normal vector at . Similarly is used for traces on .
Moreover, denotes the usual Sobolev space that is normed by \|u\|_{m}=\big{(}\sum_{|\alpha|\leq m}\int_{\Omega}|\partial^{\alpha}u|^{2}\,dx\big{)}^{1/2}, which up to equivalent norms equals the space of restrictions to of endowed with the infimum norm.
Correspondingly the dual of e.g. has an identification with the closed subspace of given by the support condition in
[TABLE]
For these matters the reader is referred to [16, App. B.2]. Chapter 6 and (9.25) in [12] could also be references for this and basic facts on boundary value problems; cf. also [9, 27].
The main result in Theorem 1 applies to (48) for , and , for which there are inclusions , when via (extension by zero outside of ) is identified with belonging to . The Dirichlet form
[TABLE]
satisfies , and the coercivity in (1) holds for , since .
The induced Lax–Milgram operator is the Neumann realisation , which is selfadjoint due to the symmetry of and has its domain given by D(\operatorname{\Delta}_{N})=\bigl{\{}\,u\in H^{2}(\Omega)\bigm{|}\gamma_{1}u=0\,\bigr{\}}. This is a classical but non-trivial result (cf. the remarks prior to Theorem 4.28 in [12], or Section 11.3 ff. there; or [27]). Thus the homogeneous boundary condition is imposed via the condition for .
By the coercivity, generates an analytic semigroup of injections in , and the bounded extension induces the analytic semigroup on ; both are defined for . As previously, .
The action of is (slightly surprisingly) given by for each , for when coincides with in , then (50) gives
[TABLE]
To make a further identification one may recall the formula , valid for when denotes the characteristic function of , and , the restriction to and the surface measure at , respectively; a proof is given in [16, Thm. 3.1.9]. Replacing by for some , and using that is a smooth vector field around , we obtain that . This now extends to all by density and continuity, and by summation one finds that in ,
[TABLE]
Clearly the last term vanishes for ; whence identifies in with the -function for such . But for general in the form domain , none of the terms on the right-hand side make sense.
The solution space for (48) amounts to
[TABLE]
The corresponding data space is here given in terms of , cf. (7), as
[TABLE]
With this framework, Theorem 1 at once gives the following new result on a classical problem:
Theorem 2**.**
Let be the Neumann realization of the Laplacian in and its extension . When and , then there exists a solution of
[TABLE]
if and only if the data are given in , i.e. if and only if
[TABLE]
In the affirmative case, is uniquely determined in and satisfies the estimate . It is given by the formula, in which all terms belong to ,
[TABLE]
Furthermore the difference in (56) equals in .
Besides the fact that appears in the differential equation (instead of ), it is noteworthy that there is no information on the boundary condition. However, there is at least one simple remedy for this, for it is well known in analytic semigroup theory, cf. [26, Thm. 4.2.3] and [26, Cor. 4.3.3], that if the source term is valued in and satisfies a global condition of Hölder continuity, that is, for some ,
[TABLE]
then the integral in (6) takes values in for and is continuous .
When this is applied in the above framework, the additional Hölder continuity yields u(t)\in D(\operatorname{\Delta}_{N})=\bigl{\{}\,u\in H^{2}(\Omega)\bigm{|}\gamma_{1}u=0\,\bigr{\}} for , so the homogeneous Neumann condition is fulfilled and identifies with , as noted after (52). Therefore one has the following novelty:
Theorem 3**.**
If and is Hölder continuous of some order , and if fulfils the criterion (56), then the homogeneous Neumann heat conduction final value problem (48) has a uniquely determined solution in , satisfying u(t)\in\bigl{\{}\,u\in H^{2}(\Omega)\bigm{|}\gamma_{1}u=0\,\bigr{\}} for , and depending continuously on in . Hence the problem is well posed in the sense of Hadamard.
It would be desirable, of course, to show the well-posedness in a strong form, with an isomorphism between the data and solution spaces.
5. Final remarks
Remark 7*.*
Grubb and Solonnikov [13] systematically treated a large class of initial-boundary problems of parabolic pseudo-differential equations and worked out compatibility conditions characterising well-posedness in full scales of anisotropic -Sobolev spaces (such conditions have a long history in the differential operator case, going back at least to work of Lions and Magenes [24] and Ladyzenskaya, Solonnikov and Ural’ceva [22]). Their conditions are explicit and local at the curved corner , except for half-integer values of the smoothness that were shown to require so-called coincidence, which is expressed in integrals over the Cartesian product of the two boundaries and ; hence coincidence is also a non-local condition. Whilst the conditions of Grubb and Solonnikov are decisive for the solution’s regularity, condition (9) in Theorem 1 is in comparison crucial for the existence question.
Remark 8*.*
Injectivity of the linear map for the homogeneneous equation , or equivalently its backwards uniqueness, was proved much earlier for problems with -dependent sesquilinear forms by Lions and Malgrange [23]. In addition to some -regularity properties in , they assumed that (the principal part of) is symmetric and uniformly -coercive in the sense that for certain fixed , and all . In Problem 3.4 of [23], they asked whether backward uniqueness can be shown without assuming symmetry (i.e., for non-selfadjoint operators in the principal case), or more precisely under the hypothesis .
The present paper gives an affirmative answer for the -independent case of their problem.
The reference list from the paper itself. Each links out to its DOI / PubMed record.
- 1[1] Y. Almog and B. Helffer, On the spectrum of non-selfadjoint Schrödinger operators with compact resolvent , Comm. PDE 40 (2015), no. 8, 1441–1466.
- 2[2] H. Amann, Linear and quasilinear parabolic problems. Vol. I , Monographs in Mathematics, vol. 89, Birkhäuser Boston, Inc., Boston, MA, 1995, Abstract linear theory.
- 3[3] W. Arendt, C. J. K. Batty, M. Hieber, and F. Neubrander, Vector-valued Laplace transforms and Cauchy problems , second ed., Monographs in Mathematics, vol. 96, Birkhäuser/Springer Basel AG, Basel, 2011.
- 4[4] A.-E. Christensen and J. Johnsen, On parabolic final value problems and well-posedness , C. R. Acad. Sci. Paris, Ser. I 356 (2018), 301–305.
- 5[5] A.-E. Christensen and J. Johnsen, Final value problems for parabolic differential equations and their well-posedness , Axioms 7 (2018), article no. 31; 1–36.
- 6[6] R. Courant and D. Hilbert, Methods of mathematical physics. Vol. I , Interscience Publishers, Inc., New York, N.Y., 1953.
- 7[7] E. B. Davies, One-parameter semigroups , London Mathematical Society Monographs, vol. 15, Academic Press, Inc., London-New York, 1980.
- 8[8] L. Eldén, Approximations for a Cauchy problem for the heat equation , Inverse Problems, 3 (1987), 263–273.
