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On finding solutions of a Kirchhoff type problem

Analysis of PDEs 2015-07-21 v1

Abstract

Consider the following Kirchhoff type problem \left\{\aligned -\bigg(a+b\int_{\mathbb{B}_R}|\nabla u|^2dx\bigg)\Delta u&= \lambda u^{q-1} + \mu u^{p-1}, &\quad \text{in}\mathbb{B}_R, \\ u&>0,&\quad\text{in}\mathbb{B}_R,\\ u&=0,&\quad\text{on}\partial\mathbb{B}_R, \endaligned \right.\eqno{(\mathcal{P})} where BR\bbrN(N3)\mathbb{B}_R\subset \bbr^N(N\geq3) is a ball, 2q<p2:=2NN22\leq q<p\leq2^*:=\frac{2N}{N-2} and aa, bb, λ\lambda, μ\mu are positive parameters. By introducing some new ideas and using the well-known results of the problem (P)(\mathcal{P}) in the cases of a=μ=1a=\mu=1 and b=0b=0, we obtain some special kinds of solutions to (P)(\mathcal{P}) for all N3N\geq3 with precise expressions on the parameters aa, bb, λ\lambda, μ\mu, which reveals some new phenomenons of the solutions to the problem (P)(\mathcal{P}). It is also worth to point out that it seems to be the first time that the solutions of (P)(\mathcal{P}) can be expressed precisely on the parameters aa, bb, λ\lambda, μ\mu, and our results in dimension four also give a partial answer to Neimen's open problems [J. Differential Equations, 257 (2014), 1168--1193]. Furthermore, our results in dimension four seems to be almost "optimal".

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Cite

@article{arxiv.1507.05392,
  title  = {On finding solutions of a Kirchhoff type problem},
  author = {Yisheng Huang and Zeng Liu and Yuanze Wu},
  journal= {arXiv preprint arXiv:1507.05392},
  year   = {2015}
}

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R2 v1 2026-06-22T10:14:49.206Z