Litcius/Paper detail

Tunable phononic bandgap materials designed via topology optimization

Anna Dalklint, Mathias Wallin, Katia Bertoldi, Daniel A. Tortorelli

2022Journal of the Mechanics and Physics of Solids73 citationsDOIOpen Access PDF

Abstract

Topology optimization is used to design phononic bandgap materials that are tunable by mechanical deformation. A periodic media is considered, which due to the assumption of length scale separation, allows the dispersion relations to be obtained by analyzing a single unit cell subjected to Floquet–Bloch boundary conditions. A finite macroscopic deformation is applied to the unit cell to affect its geometry and hence dispersion. We tune the dispersion–deformation relation to our liking by solving a topology optimization problem using nonlinear programming. The adjoint method is employed to compute the sensitivities, and the non-differentiability of degenerate eigenvalues is avoided using symmetric polynomials. Several tunable phononic crystal designs are presented. Also, a verification analysis is performed, wherein the optimized design is interpreted and analyzed using a conforming finite element mesh.

Topics & Concepts

Topology optimizationTopology (electrical circuits)Finite element methodDispersion (optics)Materials scienceMetamaterialMathematical analysisBoundary value problemPhotonic crystalNonlinear systemPeriodic boundary conditionsDeformation (meteorology)Eigenvalues and eigenvectorsBand gapHomogenization (climate)Dispersion relationBloch waveMathematicsPhysicsOpticsCondensed matter physicsComposite materialOptoelectronicsThermodynamicsQuantum mechanicsEcologyBiologyCombinatoricsBiodiversityAcoustic Wave Phenomena ResearchTopology Optimization in EngineeringComposite Structure Analysis and Optimization
Tunable phononic bandgap materials designed via topology optimization | Litcius