Proposal of finite element analysis method for dielectric breakdown based on Maxwell’s equations

This paper proposes a new approach to the simulation of discharge phenomena in dielectric breakdown including field fluctuations based on Maxwell’s equations in the finite element framework without introducing the artificial stochastic disturbance. This method is based on the idea that field fluctua...

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Bibliographic Details
Published inComputer methods in applied mechanics and engineering Vol. 371; p. 113295
Main Authors Noguchi, Satoshi, Nakamichi, Misumi, Oguni, Kenji
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.11.2020
Elsevier BV
Subjects
Bifurcations
Computer simulation
Constraint modelling
Dielectric breakdown
Discharge
Discharge patterns
Electrical resistivity
Electromagnetic radiation
Equivalent circuits
Finite element method
Inhomogeneity
Maxwell's equations
Resistors
Static electricity
Treeing
Finite element method
Dielectric breakdown
Discharge patterns
Maxwell’s equations
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Summary:This paper proposes a new approach to the simulation of discharge phenomena in dielectric breakdown including field fluctuations based on Maxwell’s equations in the finite element framework without introducing the artificial stochastic disturbance. This method is based on the idea that field fluctuations caused by the development of electrical treeing propagates as electromagnetic wave governed by Maxwell’s equations, and triggers next dielectric breakdown in a chain reaction. The obtained model can be regarded as the equivalent circuit model in which the resistors representing local property of material are arranged. The key point of the proposed method is the ease of expressing dielectric breakdown as replacement of the arranged resistors. Dielectric breakdown expressed as the local change of conductivity leads to the inhomogeneity of the conductivity. In addition to this simplest model for dielectric breakdown, constraint on the discharge paths to the finite edges in the circuit is applied. This corresponds to the introduction of the implicit inhomogeneity. This implicit inhomogeneity plays a significant role in the process of formation of branching discharge patterns. The capability of introduction of the implicit inhomogeneity and the constraint on the possible candidates for propagation paths enable the proposed method to find out a bifurcated solution and make it easier to analyze formation of discharge patterns in dielectric breakdown. This paper explains these features of the proposed mathematical model with results of numerical simulation of several example problems. •A deterministic model of dielectric breakdown based on Maxwell’s equations.•Rigorous finite element formulation of the equivalent circuit model.•Easy treatment of dielectric breakdown as replacement of resistors in the circuit.•The natural introduction of local irregular imperfections by unstructured meshes.•Stochastic features are implicitly embedded into the discretized model.
ISSN:0045-7825
1879-2138
DOI:10.1016/j.cma.2020.113295