Uniform Shapiro-Lopatinski Conditions and Boundary Value Problems on Manifolds with Bounded Geometry

Große, Nadine; Nistor, Victor

doi:10.1007/s11118-019-09774-y

Cited by 16 publications

(35 citation statements)

References 63 publications

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“…In particular, we can assume that

\begin{matrix} true \\ right ∥ P_{j} {u false∥}_{H^{k - 1} (b false(r false))} \geq ∥ P_{\infty} {u false∥}_{H^{k - 1} (b false(r false))} - ε_{j} {false∥ u false∥}_{H^{k + 1} (b false(r false))}, \end{matrix}

for all

u \in H^{k + 1} false(b (r) false)

, where

ε_{j} \to 0

j \to \infty

independent of w . The main point of this proof (exploited in greater generality in ) is that

P_{\infty}

also satisfies elliptic regularity. This is because it is strongly elliptic, since this property is preserved by limits in which the strong ellipticity constant is bounded from below and strongly elliptic operators with Dirichlet boundary conditions satisfy elliptic regularity (see the references above).…”

Section: Invertibility Of the Laplace Operatormentioning

confidence: 97%

“…If

u \in H_{D}^{1} false(M false)

and

Δ u = j_{k} false(f, g false)

, then we say that f is the “classical”

Δ u

and that

g = \partial_{ν} u

. These elementary but tedious details pertain more to analysis than geometry, so we skip the simple proofs (the reader can see more details in a more general setting in ), which however follow a different line than the one indicated here. A more substantial remark is that strongly elliptic operators with Neumann boundary conditions still satisfy elliptic regularity, so the proof of Lemma extends to the case of Neumann boundary conditions.…”

Section: Invertibility Of the Laplace Operatormentioning

confidence: 99%

“…Some of them were included in the first version of the associated ArXiv preprint, 1611.00281.v1, which had a slightly different title and will not be published in that form. The results of that preprint that were not already included in this paper, as well as others, will be included in two forthcoming papers .…”

Section: Invertibility Of the Laplace Operatormentioning

confidence: 99%

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Well‐posedness of the Laplacian on manifolds with boundary and bounded geometry

Ammann

Große

Nistor

2019

Mathematische Nachrichten

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Let M be a Riemannian manifold with a smooth boundary. The main question we address in this article is: “When is the Laplace–Beltrami operator Δ:Hk+1false(Mfalse)∩H01false(Mfalse)→Hk−1false(Mfalse), k∈double-struckN0, invertible?” We consider also the case of mixed boundary conditions. The study of this main question leads us to the class of manifolds with boundary and bounded geometry introduced by Schick (Math. Nachr. 223 (2001), 103–120). We thus begin with some needed results on the geometry of manifolds with boundary and bounded geometry. Let ∂DM⊂∂M be an open and closed subset of the boundary of M. We say that (M,∂DM) has finite width if, by definition, M is a manifold with boundary and bounded geometry such that the distance dist(x,∂DM) from a point x∈M to ∂DM⊂∂M is bounded uniformly in x (and hence, in particular, ∂DM intersects all connected components of M). For manifolds (M,∂DM) with finite width, we prove a Poincaré inequality for functions vanishing on ∂DM, thus generalizing an important result of Sakurai (Osaka J. Math, 2017). The Poincaré inequality then leads, as in the classical case to results on the spectrum of Δ with domain given by mixed boundary conditions, in particular, Δ is invertible for manifolds (M,∂DM) with finite width. The bounded geometry assumption then allows us to prove the well‐posedness of the Poisson problem with mixed boundary conditions in the higher Sobolev spaces Hsfalse(Mfalse), s≥0.

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“…In particular, we can assume that

\begin{matrix} true \\ right ∥ P_{j} {u false∥}_{H^{k - 1} (b false(r false))} \geq ∥ P_{\infty} {u false∥}_{H^{k - 1} (b false(r false))} - ε_{j} {false∥ u false∥}_{H^{k + 1} (b false(r false))}, \end{matrix}

for all

u \in H^{k + 1} false(b (r) false)

, where

ε_{j} \to 0

j \to \infty

independent of w . The main point of this proof (exploited in greater generality in ) is that

P_{\infty}

Section: Invertibility Of the Laplace Operatormentioning

confidence: 97%

“…If

u \in H_{D}^{1} false(M false)

and

Δ u = j_{k} false(f, g false)

, then we say that f is the “classical”

Δ u

and that

g = \partial_{ν} u

Section: Invertibility Of the Laplace Operatormentioning

confidence: 99%

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Well‐posedness of the Laplacian on manifolds with boundary and bounded geometry

Ammann

Große

Nistor

2019

Mathematische Nachrichten

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“…Let ∂ a ν be the conormal derivative associated to P , see [14]. Combining Theorem 6 with the Lax-Milgram Lemma and with the fact that the Dirichlet and Neumann boundary conditions satify the uniform Shapiro-Lopatinski regularity conditions [5,14], we obtain: Theorem 8. We assume that (M, ∂ 0 M, E, g 0 , ρ) satisfies the Hardy-Poincaré inequality.…”

mentioning

confidence: 92%

“…We assume from now on that we are given a partition of the boundary ∂M = ∂ 0 M ⊔ ∂ 1 M into two disjoint, open subsets, as in [5], and order i differential boundary conditions B i on ∂ i M . See, for example, [7,20] for general results on boundary value problems on smooth domains, [11,18,23,22] for the case of non-smooth domains, and [4,14] for more general boundary conditions involving projections. We assume that ρ 2 P , ρB 1 , and B 0 have coefficients in W ∞,∞ (g).…”

mentioning

confidence: 99%

Analysis and boundary value problems on singular domains: An approach via bounded geometry

Ammann

Große

Nistor

2019

Comptes Rendus. Mathématique

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We prove well-posedness and regularity results for elliptic boundary value problems on certain singular domains that are conformally equivalent to manifolds with boundary and bounded geometry. Our assumptions are satisfied by the domains with a smooth set of singular cuspidal points, and hence our results apply to the class of domains with isolated oscillating conical singularities. In particular, our results generalize the classical L 2 -well-posedness result of Kondratiev for the Laplacian on domains with conical points. However, our domains and coefficients are too general to allow for singular function expansions of the solutions similar to the ones in Kondratiev's theory. The proofs are based on conformal changes of metric, on the differential geometry of manifolds with boundary and bounded geometry, and on our earlier geometric and analytic results on such manifolds.

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On the construction of the Stokes flow in a domain with cylindrical ends

Wendland

2024

Math Methods in App Sciences

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Based on existence results for the Stokes operator and its solution properties in manifolds with cylindrical ends by Große et al. and Kohr et al., the Stokes flow in a three‐dimensional compact domain with circular openings through which the fluid enters and leaves through unbounded cylindrical pipes the Stokes flow is modeled as a mixed boundary value problem whereas in the cylindrical ends, the velocities and pressures are constant on every straight line in the cylindrical directions with initial values from the openings of . These values equal the velocities and pressures which are obtained from the mixed boundary values' solution in at the openings .

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Uniform Shapiro-Lopatinski Conditions and Boundary Value Problems on Manifolds with Bounded Geometry

Cited by 16 publications

References 63 publications

Well‐posedness of the Laplacian on manifolds with boundary and bounded geometry

Well‐posedness of the Laplacian on manifolds with boundary and bounded geometry

Analysis and boundary value problems on singular domains: An approach via bounded geometry

On the construction of the Stokes flow in a domain with cylindrical ends

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