The 2024 phononic crystals roadmap

Yabin Jin; Daniel Torrent; Bahram Djafari Rouhani; Liangshu He; Yanxun Xiang; Fu Zhen Xuan; Zhongming Gu; Haoran Xue; Jie Zhu; Qian Wu; Guoliang Huang; Pedro David García; Guillermo Arregui; Yi Chen; Sébastien Guenneau; Martin Wegener; Muamer Kadic; Yongquan Liu; Jensen Li; Yue Sheng Wang; Antonio Palermo; V. Romero-García; S. Kuznetsova; I. Cheron; M. Lázaro Navarro; J. P. Groby; V. Pagneux; S. Félix; L. M. Garcia-Raffi; Gengkai Hu; Runcheng Cai; Timon Rabczuk; Xiaoying Zhuang; Penglin Gao; Yegao Qu; Mahmoud I. Hussein; Masahiro Nomura; Yan Pennec; Feiyan Cai; Xinwei Li; Wei Zhai

doi:10.1088/1361-6463/ad9ab2

The 2024 phononic crystals roadmap

Yabin Jin
, Daniel Torrent
, Bahram Djafari Rouhani
, Liangshu He
, Yanxun Xiang
, Fu Zhen Xuan
, Zhongming Gu
, Haoran Xue
, Jie Zhu
, Qian Wu
, Guoliang Huang
, Pedro David García
, Guillermo Arregui
, Yi Chen
, Sébastien Guenneau
, Martin Wegener
, Muamer Kadic
, Yongquan Liu
, Jensen Li
, Yue Sheng Wang

Antonio Palermo, V. Romero-García, S. Kuznetsova, I. Cheron, M. Lázaro Navarro, J. P. Groby, V. Pagneux, S. Félix, L. M. Garcia-Raffi, Gengkai Hu, Runcheng Cai, Timon Rabczuk, Xiaoying Zhuang, Penglin Gao, Yegao Qu, Mahmoud I. Hussein, Masahiro Nomura, Yan Pennec, Feiyan Cai, Xinwei Li, Wei Zhai

School of Aerospace Engineering

East China University of Science and Technology
Shanghai Institute of Aircraft Mechanics and Control
Jaume I University
Université de Lille
Tongji University
Chinese University of Hong Kong
University of Missouri
Consejo Superior de Investigaciones Científicas
Swiss Federal Institute of Technology Lausanne
Karlsruhe Institute of Technology
Imperial College London
Université Marie et Louis Pasteur
Hong Kong University of Science and Technology
Tianjin University
University of Bologna
Polytechnic University of Valencia
UMR 6613 CNRS
Beijing Institute of Technology
Bauhaus-Universität Weimar
Leibniz University Hannover
Shanghai Jiao Tong University
University of Colorado Boulder
The University of Tokyo
Shenzhen Institute of Advanced Technology
Newcastle University
National University of Singapore

Research output: Contribution to journal › Review article › peer-review

26 Scopus citations

Abstract

Over the past 3 decades, phononic crystals experienced revolutionary development for understanding and utilizing mechanical waves by exploring interaction between mechanical waves and structures. With the significant advances in manufacture technologies from nanoscale to macroscale, phononic crystals attract researchers from diverse disciplines to study abundant directions such as bandgaps, dispersion engineering, novel modes, reconfigurable control, efficient design algorithms and so on. The aim of this roadmap is to present the current state of the art, an overview of properties, functions and applications of phononic crystals, opinions on the challenges and opportunities. The various perspectives cover wide topics on basic property, homogenization, machine learning assisted design, topological, non-Hermitian, nonreciprocal, nanoscale, chiral, nonlocal, active, spatiotemporal, hyperuniform properties of phononic crystals, and applications in underwater acoustics, seismic wave protection, vibration and noise control, thermal transport, sensing, acoustic tweezers, written by over 40 renown experts. It is also intended to guide researchers, funding agencies and industry in identifying new prospects for phononic crystals in the upcoming years.

Original language	English
Article number	113001
Journal	Journal of Physics D: Applied Physics
Volume	58
Issue number	11
DOIs	https://doi.org/10.1088/1361-6463/ad9ab2
State	Published - 17 Mar 2025

Keywords

bandgap
homogenization
nanophononic crystals
noise and vibration control
nonreciprocal phononic crystals
phononic crystals
topological phononic crystals

Access to Document

10.1088/1361-6463/ad9ab2

Cite this

@article{5700ccafcb41434ebc3953d8f04f1760,

title = "The 2024 phononic crystals roadmap",

abstract = "Over the past 3 decades, phononic crystals experienced revolutionary development for understanding and utilizing mechanical waves by exploring interaction between mechanical waves and structures. With the significant advances in manufacture technologies from nanoscale to macroscale, phononic crystals attract researchers from diverse disciplines to study abundant directions such as bandgaps, dispersion engineering, novel modes, reconfigurable control, efficient design algorithms and so on. The aim of this roadmap is to present the current state of the art, an overview of properties, functions and applications of phononic crystals, opinions on the challenges and opportunities. The various perspectives cover wide topics on basic property, homogenization, machine learning assisted design, topological, non-Hermitian, nonreciprocal, nanoscale, chiral, nonlocal, active, spatiotemporal, hyperuniform properties of phononic crystals, and applications in underwater acoustics, seismic wave protection, vibration and noise control, thermal transport, sensing, acoustic tweezers, written by over 40 renown experts. It is also intended to guide researchers, funding agencies and industry in identifying new prospects for phononic crystals in the upcoming years.",

keywords = "bandgap, homogenization, nanophononic crystals, noise and vibration control, nonreciprocal phononic crystals, phononic crystals, topological phononic crystals",

author = "Yabin Jin and Daniel Torrent and Rouhani, \{Bahram Djafari\} and Liangshu He and Yanxun Xiang and Xuan, \{Fu Zhen\} and Zhongming Gu and Haoran Xue and Jie Zhu and Qian Wu and Guoliang Huang and Garc{\'i}a, \{Pedro David\} and Guillermo Arregui and Yi Chen and S{\'e}bastien Guenneau and Martin Wegener and Muamer Kadic and Yongquan Liu and Jensen Li and Wang, \{Yue Sheng\} and Antonio Palermo and V. Romero-Garc{\'i}a and S. Kuznetsova and I. Cheron and \{L{\'a}zaro Navarro\}, M. and Groby, \{J. P.\} and V. Pagneux and S. F{\'e}lix and Garcia-Raffi, \{L. M.\} and Gengkai Hu and Runcheng Cai and Timon Rabczuk and Xiaoying Zhuang and Penglin Gao and Yegao Qu and Hussein, \{Mahmoud I.\} and Masahiro Nomura and Yan Pennec and Feiyan Cai and Xinwei Li and Wei Zhai",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Published by IOP Publishing Ltd.",

year = "2025",

month = mar,

day = "17",

doi = "10.1088/1361-6463/ad9ab2",

language = "英语",

volume = "58",

journal = "Journal of Physics D: Applied Physics",

issn = "0022-3727",

publisher = "Institute of Physics",

number = "11",

}

Jin, Y, Torrent, D, Rouhani, BD, He, L, Xiang, Y, Xuan, FZ, Gu, Z, Xue, H, Zhu, J, Wu, Q, Huang, G, García, PD, Arregui, G, Chen, Y, Guenneau, S, Wegener, M, Kadic, M, Liu, Y, Li, J, Wang, YS, Palermo, A, Romero-García, V, Kuznetsova, S, Cheron, I, Lázaro Navarro, M, Groby, JP, Pagneux, V, Félix, S, Garcia-Raffi, LM, Hu, G, Cai, R, Rabczuk, T, Zhuang, X, Gao, P, Qu, Y, Hussein, MI, Nomura, M, Pennec, Y, Cai, F, Li, X & Zhai, W 2025, 'The 2024 phononic crystals roadmap', Journal of Physics D: Applied Physics, vol. 58, no. 11, 113001. https://doi.org/10.1088/1361-6463/ad9ab2

TY - JOUR

T1 - The 2024 phononic crystals roadmap

AU - Jin, Yabin

AU - Torrent, Daniel

AU - Rouhani, Bahram Djafari

AU - He, Liangshu

AU - Xiang, Yanxun

AU - Xuan, Fu Zhen

AU - Gu, Zhongming

AU - Xue, Haoran

AU - Zhu, Jie

AU - Wu, Qian

AU - Huang, Guoliang

AU - García, Pedro David

AU - Arregui, Guillermo

AU - Chen, Yi

AU - Guenneau, Sébastien

AU - Wegener, Martin

AU - Kadic, Muamer

AU - Liu, Yongquan

AU - Li, Jensen

AU - Wang, Yue Sheng

AU - Palermo, Antonio

AU - Romero-García, V.

AU - Kuznetsova, S.

AU - Cheron, I.

AU - Lázaro Navarro, M.

AU - Groby, J. P.

AU - Pagneux, V.

AU - Félix, S.

AU - Garcia-Raffi, L. M.

AU - Hu, Gengkai

AU - Cai, Runcheng

AU - Rabczuk, Timon

AU - Zhuang, Xiaoying

AU - Gao, Penglin

AU - Qu, Yegao

AU - Hussein, Mahmoud I.

AU - Nomura, Masahiro

AU - Pennec, Yan

AU - Cai, Feiyan

AU - Li, Xinwei

AU - Zhai, Wei

PY - 2025/3/17

Y1 - 2025/3/17

N2 - Over the past 3 decades, phononic crystals experienced revolutionary development for understanding and utilizing mechanical waves by exploring interaction between mechanical waves and structures. With the significant advances in manufacture technologies from nanoscale to macroscale, phononic crystals attract researchers from diverse disciplines to study abundant directions such as bandgaps, dispersion engineering, novel modes, reconfigurable control, efficient design algorithms and so on. The aim of this roadmap is to present the current state of the art, an overview of properties, functions and applications of phononic crystals, opinions on the challenges and opportunities. The various perspectives cover wide topics on basic property, homogenization, machine learning assisted design, topological, non-Hermitian, nonreciprocal, nanoscale, chiral, nonlocal, active, spatiotemporal, hyperuniform properties of phononic crystals, and applications in underwater acoustics, seismic wave protection, vibration and noise control, thermal transport, sensing, acoustic tweezers, written by over 40 renown experts. It is also intended to guide researchers, funding agencies and industry in identifying new prospects for phononic crystals in the upcoming years.

AB - Over the past 3 decades, phononic crystals experienced revolutionary development for understanding and utilizing mechanical waves by exploring interaction between mechanical waves and structures. With the significant advances in manufacture technologies from nanoscale to macroscale, phononic crystals attract researchers from diverse disciplines to study abundant directions such as bandgaps, dispersion engineering, novel modes, reconfigurable control, efficient design algorithms and so on. The aim of this roadmap is to present the current state of the art, an overview of properties, functions and applications of phononic crystals, opinions on the challenges and opportunities. The various perspectives cover wide topics on basic property, homogenization, machine learning assisted design, topological, non-Hermitian, nonreciprocal, nanoscale, chiral, nonlocal, active, spatiotemporal, hyperuniform properties of phononic crystals, and applications in underwater acoustics, seismic wave protection, vibration and noise control, thermal transport, sensing, acoustic tweezers, written by over 40 renown experts. It is also intended to guide researchers, funding agencies and industry in identifying new prospects for phononic crystals in the upcoming years.

KW - bandgap

KW - homogenization

KW - nanophononic crystals

KW - noise and vibration control

KW - nonreciprocal phononic crystals

KW - phononic crystals

KW - topological phononic crystals

UR - https://www.scopus.com/pages/publications/85218622660

U2 - 10.1088/1361-6463/ad9ab2

DO - 10.1088/1361-6463/ad9ab2

M3 - 文献综述

AN - SCOPUS:85218622660

SN - 0022-3727

VL - 58

JO - Journal of Physics D: Applied Physics

JF - Journal of Physics D: Applied Physics

IS - 11

M1 - 113001

ER -

The 2024 phononic crystals roadmap

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Keywords

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