Finite and infinite energy solutions of singular elliptic problems: Existence and uniqueness

Oliva, Francescantonio; Petitta, Francesco

doi:10.1016/j.jde.2017.09.008

Cited by 67 publications

(49 citation statements)

References 40 publications

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“…where L denotes the Lipschitz constant of h. Moreover, it follows from Remark 4.8. The BV -estimate proven in Step 2 depends only on the fact that γ > 0 (see (37)). We point out that in the nonsingular setting (when γ = 0) this fact does not hold, unless f is small enough.…”

Section: Resultsmentioning

confidence: 99%

“…Problem (2) for p = 2 was initially proposed in 1960 in the pioneering work by Fulks and Maybee [21] as a model for several physical situations. This problem was then studied by many authors, among which we will quote the works of Stuart [42], Crandall, Rabinowitz and Tartar [16], Lazer and McKenna [30], Boccardo and Orsina [8], Coclite and Coclite [15], Arcoya and Moreno-Mérida [6], Oliva and Petitta [37], and Giachetti, Martinez-Aparicio and Murat [22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

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Elliptic problems involving the 1–Laplacian and a singular lower order term

Cicco

Giachetti

León

2018

J. London Math. Soc.

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This paper is concerned with the Dirichlet problem for an equation involving the 1–Laplacian operator normalΔ1u:=divfalse(Dufalse|Dufalse|false) and having a singular term of the type ffalse(xfalse)uγ. Here f∈LNfalse(normalΩfalse) is nonnegative, 0<γ⩽1 and normalΩ is an open bounded set with Lipschitz‐continuous boundary. We prove an existence result for a concept of solution conveniently defined. The solution is obtained as limit of solutions to p‐Laplacian type problems. Moreover, when f(x)>0 almost everywhere, the solution satisfies those features that might be expected as well as a uniqueness result. We also give explicit one–dimensional examples that show that, in general, uniqueness does not hold. We remark that the Anzellotti theory of L∞–divergence–measure vector fields must be extended to deal with this equation.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Elliptic problems involving the 1–Laplacian and a singular lower order term

Cicco

Giachetti

León

2018

J. London Math. Soc.

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“…Otherwise if is not sufficiently regular we are just able to prove that, in general, every truncation of the solution has locally finite energy. For this kind of effects and even more we refer to [11,26,47,48]. When = 1 the same effect arises: for instance in [28] it is proved the existence of a locally BV -solution if is in L N (Ω).…”

mentioning

confidence: 91%

“…Moreover if γ = 1 the solution is always in H 1 0 (Ω) even if is just an L 1 -function as one can formally deduce by taking itself as test function in (1.1) while if γ > 1 the solution belongs only locally to H 1 (Ω) and the boundary datum is given as a suitable power of the solution having zero Sobolev trace. Then, in [48], a general (as above) is considered and various results are proved depending on γ, θ, and in order to have finite energy solutions. Among other things, one of the results concerning finite energy solutions can be summarized as follows: let 0 ≤ γ ≤ 1 then ∈ H 1 0 (Ω) if 0 ≤ θ < 1 and ∈ L ( 2 * 1−θ ) ′ (Ω) or if θ ≥ 1 and is just an L 1 -function.…”

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confidence: 99%

Regularizing effect of absorption terms in singular problems

Oliva

2019

Journal of Mathematical Analysis and Applications

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A. We prove existence of solutions to problems whose model iswhere Ω is an open bounded subset of R N (N ≥ 2), ∆ is the -laplacian operator for 1 ≤ < N, > 0, γ ≥ 0 and is a nonnegative function in L (Ω) for some ≥ 1. In particular we analyze the regularizing effect produced by the absorption term in order to infer the existence of finite energy solutions in case γ ≤ 1. We also study uniqueness of these solutions as well as examples which show the optimality of the results. Finally, we find local W 1 -solutions in case γ > 1.

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“…Using dominated convergence theorem one can pass to the limit also on the right hand side of (4.2) and we conclude. (Ω) (see [22,6,31]), one has, by Lemma 4.2, that ( ) = ( ) turns out to be a finite energy solution of (P 0 ).…”

mentioning

confidence: 96%

A nonlinear parabolic problem with singular terms and nonregular data

Oliva

Petitta

2020

Nonlinear Analysis

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A. We study existence of nonnegative solutions to a nonlinear parabolic boundary value problem with a general singular lower order term and a nonnegative measure as nonhomogeneous datum, of the formwhere Ω is an open bounded subset of R N (N ≥ 2), 0 is a nonnegative integrable function, ∆ is the -laplace operator, µ is a nonnegative bounded Radon measure on Ω × (0 T ) and is a nonnegative function of L 1 (Ω × (0 T )). The term is a positive continuous function possibly blowing up at the origin. Furthermore, we show uniqueness of finite energy solutions in presence of a nonincreasing .

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Finite and infinite energy solutions of singular elliptic problems: Existence and uniqueness

Cited by 67 publications

References 40 publications

Elliptic problems involving the 1–Laplacian and a singular lower order term

Elliptic problems involving the 1–Laplacian and a singular lower order term

Regularizing effect of absorption terms in singular problems

A nonlinear parabolic problem with singular terms and nonregular data

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