English

Radial single point rupture solutions for a general MEMS model

Analysis of PDEs 2020-06-11 v2

Abstract

We study the initial value problem {r(γ1)(rαuβ1u)=1f(u)for 0<r<r0,u(r)>0for 0<r<r0,u(0)=0, \begin{cases} r^{-(\gamma-1)}\left(r^{\alpha}|u'|^{\beta-1}u'\right)'=\frac{1}{f(u)} & \textrm{for}\ 0<r<r_0,\\ u(r)>0 & \textrm{for}\ 0<r<r_0,\\ u(0)=0, \end{cases} for γ>α>β1\gamma>\alpha>\beta\geq 1 and fC[0,uˉ)C2(0,uˉ)f\in C[0,\bar u)\cap C^2(0,\bar u), f(0)=0f(0)=0, f(u)>0f(u)>0 on (0,uˉ)(0, \bar u) and ff satisfies certain assumptions which include the standard case of pure power nonlinearities encountered in the study of Micro-Electromechanical Systems (MEMS). We obtain the existence and uniqueness of a solution uu^* to the above problem, the rate at which it approaches the value zero at the origin and the intersection number of points with the corresponding regular solutions u(,a)u(\,\cdot\,,a) (with u(0,a)=au(0,a)=a) as a0a\to 0. In particular, these results yield the uniqueness of a radial single point rupture solution and other qualitative properties for MEMS models. The bifurcation diagram is also investigated.

Cite

@article{arxiv.2002.12711,
  title  = {Radial single point rupture solutions for a general MEMS model},
  author = {Marius Ghergu and Yasuhito Miyamoto},
  journal= {arXiv preprint arXiv:2002.12711},
  year   = {2020}
}

Comments

29 pages

R2 v1 2026-06-23T13:57:36.937Z