Literature DB >> 12804226

Systematic design of phononic band-gap materials and structures by topology optimization.

Ole Sigmund1, Jakob Søndergaard Jensen.   

Abstract

Phononic band-gap materials prevent elastic waves in certain frequency ranges from propagating, and they may therefore be used to generate frequency filters, as beam splitters, as sound or vibration protection devices, or as waveguides. In this work we show how topology optimization can be used to design and optimize periodic materials and structures exhibiting phononic band gaps. Firstly, we optimize infinitely periodic band-gap materials by maximizing the relative size of the band gaps. Then, finite structures subjected to periodic loading are optimized in order to either minimize the structural response along boundaries (wave damping) or maximize the response at certain boundary locations (waveguiding).

Mesh:

Year:  2003        PMID: 12804226     DOI: 10.1098/rsta.2003.1177

Source DB:  PubMed          Journal:  Philos Trans A Math Phys Eng Sci        ISSN: 1364-503X            Impact factor:   4.226


  12 in total

1.  On the universality of the frequency spectrum and band-gap optimization of quasicrystalline-generated structured rods.

Authors:  Lorenzo Morini; Zafer Gökay Tetik; Gal Shmuel; Massimiliano Gei
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2019-11-25       Impact factor: 4.226

2.  Design and Additive Manufacturing of 3D Phononic Band Gap Structures Based on Gradient Based Optimization.

Authors:  Maximilian Wormser; Fabian Wein; Michael Stingl; Carolin Körner
Journal:  Materials (Basel)       Date:  2017-09-22       Impact factor: 3.623

3.  Phononic Band Gaps in 2D Quadratic and 3D Cubic Cellular Structures.

Authors:  Franziska Warmuth; Carolin Körner
Journal:  Materials (Basel)       Date:  2015-12-02       Impact factor: 3.623

4.  Optimized microwave illusion device.

Authors:  Benjamin Vial; Max Munoz Torrico; Yang Hao
Journal:  Sci Rep       Date:  2017-06-21       Impact factor: 4.379

5.  Topological Design of Cellular Phononic Band Gap Crystals.

Authors:  Yang Fan Li; Xiaodong Huang; Shiwei Zhou
Journal:  Materials (Basel)       Date:  2016-03-10       Impact factor: 3.623

6.  3-D phononic crystals with ultra-wide band gaps.

Authors:  Yan Lu; Yang Yang; James K Guest; Ankit Srivastava
Journal:  Sci Rep       Date:  2017-02-24       Impact factor: 4.379

7.  Ultrafast perturbation maps as a quantitative tool for testing of multi-port photonic devices.

Authors:  Kevin Vynck; Nicholas J Dinsdale; Bigeng Chen; Roman Bruck; Ali Z Khokhar; Scott A Reynolds; Lee Crudgington; David J Thomson; Graham T Reed; Philippe Lalanne; Otto L Muskens
Journal:  Nat Commun       Date:  2018-06-08       Impact factor: 14.919

8.  Introducing Obliquely Perforated Phononic Plates for Enhanced Bandgap Efficiency.

Authors:  Saeid Hedayatrasa; Mathias Kersemans; Kazem Abhary; Wim Van Paepegem
Journal:  Materials (Basel)       Date:  2018-07-28       Impact factor: 3.623

9.  Topological Optimization of Phononic Crystal Thin Plate by a Genetic Algorithm.

Authors:  X K Han; Z Zhang
Journal:  Sci Rep       Date:  2019-06-06       Impact factor: 4.379

10.  Bio-inspired heterogeneous composites for broadband vibration mitigation.

Authors:  Yanyu Chen; Lifeng Wang
Journal:  Sci Rep       Date:  2015-12-08       Impact factor: 4.379
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