6533b832fe1ef96bd129a5b0
RESEARCH PRODUCT
Spectral analysis of the Neumann-Poincaré operator and characterization of the stress concentration in anti-plane elasticity
Hyeonbae KangGiulio CiraoloKihyun YunHyundae LeeHabib Ammarisubject
Gradient blow upMechanical Engineering010102 general mathematicsLinear elasticityMathematical analysisEigenfunction01 natural sciencesNeumann–Poincaré operator010101 applied mathematicsanti-plane elasticityMathematics (miscellaneous)Harmonic functionSingular functionSettore MAT/05 - Analisi Matematica0101 mathematicsElasticity (economics)AnalysisEigenvalues and eigenvectorsMathematicsOsculating circledescription
When holes or hard elastic inclusions are closely located, stress which is the gradient of the solution to the anti-plane elasticity equation can be arbitrarily large as the distance between two inclusions tends to zero. It is important to precisely characterize the blow-up of the gradient of such an equation. In this paper we show that the blow-up of the gradient can be characterized by a singular function defined by the single layer potential of an eigenfunction corresponding to the eigenvalue 1/2 of a Neumann–Poincare type operator defined on the boundaries of the inclusions. By comparing the singular function with the one corresponding to two disks osculating to the inclusions, we quantitatively characterize the blow-up of the gradient in terms of explicit functions. In electrostatics, our results apply to the electric field, which is the gradient of the solution to the conductivity equation, in the case where perfectly conducting or insulating inclusions are closely located.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2012-11-15 |