Radial Solutions for p-Laplacian Neumann Problems Involving Gradient Term Without Growth Restrictions

We consider the following semilinear problem with a gradient term in the nonlinearity<disp-formula> <label/> <tex-math id="FE1"> \begin{document}$ \begin{align*} -\Delta u = \lambda \frac{(1+|\nabla u|^q)}{(1-u)^p}\quad\text{in}\quad\Omega,\quad u>0\quad \text{in}\quad \Omega, \quad u = 0\quad\text{on}\quad \partial \Omega. \end{align*} $\end{document} </tex-math></disp-formula>where <inline-formula><tex-math id="M1">\begin{document}$ \lambda,p,q>0 $\end{document}</tex-math></inline-formula> and <inline-formula><tex-math id="M2">\begin{document}$ \Omega $\end{document}</tex-math></inline-formula> be a bounded, smooth domain in <inline-formula><tex-math id="M3">\begin{document}$ {\mathbb R}^N $\end{document}</tex-math></inline-formula>. We prove that when <inline-formula><tex-math id="M4">\begin{document}$ \Omega $\end{document}</tex-math></inline-formula> is a unit ball and <inline-formula><tex-math id="M5">\begin{document}$ p = 1 $\end{document}</tex-math></inline-formula> for <inline-formula><tex-math id="M6">\begin{document}$ q\in (0,q^*(N)) $\end{document}</tex-math></inline-formula> with <inline-formula><tex-math id="M7">\begin{document}$ q^*(N)\in (1,2) $\end{document}</tex-math></inline-formula>, we have infinitely many radial solutions for <inline-formula><tex-math id="M8">\begin{document}$ 2\leq N<2\frac{6-q+2\sqrt{8-2q}}{(2-q)^2}+1 $\end{document}</tex-math></inline-formula> and <inline-formula><tex-math id="M9">\begin{document}$ \lambda = \tilde \lambda $\end{document}</tex-math></inline-formula>. On the other hand, for <inline-formula><tex-math id="M10">\begin{document}$ N>2\frac{6-q+2\sqrt{8-2q}}{(2-q)^2}+1 $\end{document}</tex-math></inline-formula> there exists a unique radial solution for <inline-formula><tex-math id="M11">\begin{document}$ 0<\lambda<\tilde \lambda $\end{document}</tex-math></inline-formula>.

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Three positive nonconstant radial solutions of nonlinear Neumann problems with indefinite weight

Applicable Analysis ◽

10.1080/00036811.2021.1979215 ◽

2021 ◽

pp. 1-12

Author(s):

T. Chen ◽

R. Ma

Keyword(s):

Indefinite Weight ◽

Radial Solutions ◽

Neumann Problems ◽

Nonlinear Neumann Problems

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Radial positive solutions for Neumann problems without growth restrictions

Complex Variables and Elliptic Equations ◽

10.1080/17476933.2016.1251420 ◽

2016 ◽

Vol 62 (6) ◽

pp. 848-861 ◽

Cited By ~ 1

Author(s):

Ruyun Ma ◽

Hongliang Gao ◽

Tianlan Chen

Keyword(s):

Positive Solutions ◽

Neumann Problems ◽

Growth Restrictions

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Radial solutions for Neumann problems involving mean curvature operators in Euclidean and Minkowski spaces

Mathematische Nachrichten ◽

10.1002/mana.200910083 ◽

2010 ◽

Vol 283 (3) ◽

pp. 379-391 ◽

Cited By ~ 29

Author(s):

Cristian Bereanu ◽

Petru Jebelean ◽

Jean Mawhin

Keyword(s):

Mean Curvature ◽

Radial Solutions ◽

Neumann Problems ◽

Minkowski Spaces

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A priori bounds and multiplicity of positive solutions for p-Laplacian Neumann problems with sub-critical growth

Proceedings of the Royal Society of Edinburgh Section A Mathematics ◽

10.1017/prm.2018.143 ◽

2019 ◽

Vol 150 (1) ◽

pp. 73-102 ◽

Cited By ~ 1

Author(s):

Alberto Boscaggin ◽

Francesca Colasuonno ◽

Benedetta Noris

Keyword(s):

Positive Solutions ◽

Critical Power ◽

A Priori ◽

Oscillatory Behaviour ◽

Radial Solutions ◽

A Priori Bounds ◽

Shooting Technique ◽

Neumann Problems ◽

Multiplicity Of Positive Solutions ◽

Image Position

AbstractLet 1 < p < +∞ and let Ω ⊂ ℝN be either a ball or an annulus. We continue the analysis started in [Boscaggin, Colasuonno, Noris, ESAIM Control Optim. Calc. Var. (2017)], concerning quasilinear Neumann problems of the type $-\Delta _pu = f(u),\quad u > 0\,{\rm in }\,\Omega ,\quad \partial _\nu u = 0\,{\rm on }\,\partial \Omega .$We suppose that f(0) = f(1) = 0 and that f is negative between the two zeros and positive after. In case Ω is a ball, we also require that f grows less than the Sobolev-critical power at infinity. We prove a priori bounds of radial solutions, focussing in particular on solutions which start above 1. As an application, we use the shooting technique to get existence, multiplicity and oscillatory behaviour (around 1) of non-constant radial solutions.

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