No touchdown at points of small permittivity and nontrivial touchdown sets for the MEMS problem
Carlos Esteve, Philippe Souplet

TL;DR
This paper investigates the conditions under which touchdown occurs in a MEMS model with variable permittivity, revealing that small permittivity regions prevent touchdown and that the touchdown set can have complex, non-localized structures.
Contribution
The study extends understanding of touchdown phenomena by analyzing small permittivity regions and constructing profiles with complex touchdown set configurations.
Findings
Touchdown cannot occur at interior points with sufficiently small permittivity.
Touchdown sets can be located far from permittivity maxima, including near minima.
Constructed profiles with touchdown sets near arbitrary points or spheres, demonstrating complex behaviors.
Abstract
We consider a well-known model for micro-electromechanical systems (MEMS) with variable dielectric permittivity, involving a parabolic equation with singular nonlinearity. We study the touchdown, or quenching, phenomenon. Recently, the question whether or not touchdown can occur at zero points of the premittivity profile f, which had long remained open, was answered negatively for the case of interior points. The first aim of this article is to go further by considering the same question at points of positive but small permittivity. We show that, in any bounded domain, touchdown cannot occur at an interior point where the permittivity profile is suitably small. We also obtain a similar result in the boundary case, under a smallness assumption on f in a neighborhood of the boundary. This allows in particular to construct f producing touchdown sets concentrated near any given sphere.…
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Taxonomy
TopicsAdvanced Mathematical Modeling in Engineering · Stability and Controllability of Differential Equations · Nonlinear Partial Differential Equations
