Publications
1.
Wang, Pai; Zheng, Yue; Fernandes, Matheus C.; Sun, Yushen; Xu, Kai; Sun, Sijie; Kang, Sung Hoon; Tournat, Vincent; Bertoldi, Katia
Harnessing Geometric Frustration to Form Band Gaps in Acoustic Channel Lattices Journal Article
In: Physical Review Letters, vol. 118, pp. 084302, 2017.
@article{Wang2017,
title = {Harnessing Geometric Frustration to Form Band Gaps in Acoustic Channel Lattices},
author = {Pai Wang and Yue Zheng and Matheus C. Fernandes and Yushen Sun and Kai Xu and Sijie Sun and Sung Hoon Kang and Vincent Tournat and Katia Bertoldi},
url = {https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.118.084302},
doi = {10.1103/PhysRevLett.118.084302},
year = {2017},
date = {2017-02-21},
journal = {Physical Review Letters},
volume = {118},
pages = {084302},
abstract = {We demonstrate both numerically and experimentally that geometric frustration in two-dimensional periodic acoustic networks consisting of arrays of narrow air channels can be harnessed to form band gaps (ranges of frequency in which the waves cannot propagate in any direction through the system). While resonant standing wave modes and interferences are ubiquitous in all the analyzed network geometries, we show that they give rise to band gaps only in the geometrically frustrated ones (i.e., those comprising of triangles and pentagons). Our results not only reveal a new mechanism based on geometric frustration to suppress the propagation of pressure waves in specific frequency ranges but also open avenues for the design of a new generation of smart systems that control and manipulate sound and vibrations.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
We demonstrate both numerically and experimentally that geometric frustration in two-dimensional periodic acoustic networks consisting of arrays of narrow air channels can be harnessed to form band gaps (ranges of frequency in which the waves cannot propagate in any direction through the system). While resonant standing wave modes and interferences are ubiquitous in all the analyzed network geometries, we show that they give rise to band gaps only in the geometrically frustrated ones (i.e., those comprising of triangles and pentagons). Our results not only reveal a new mechanism based on geometric frustration to suppress the propagation of pressure waves in specific frequency ranges but also open avenues for the design of a new generation of smart systems that control and manipulate sound and vibrations.
Note: Send e-mail to Prof. Kang at [email protected] if you need a pdf file of the papers below.
2017
Wang, Pai; Zheng, Yue; Fernandes, Matheus C.; Sun, Yushen; Xu, Kai; Sun, Sijie; Kang, Sung Hoon; Tournat, Vincent; Bertoldi, Katia
Harnessing Geometric Frustration to Form Band Gaps in Acoustic Channel Lattices Journal Article
In: Physical Review Letters, vol. 118, pp. 084302, 2017.
Abstract | Links | BibTeX | Tags: Acoustic, architected materials, Band gap, Geometrical Frustration, Metamaterial
@article{Wang2017,
title = {Harnessing Geometric Frustration to Form Band Gaps in Acoustic Channel Lattices},
author = {Pai Wang and Yue Zheng and Matheus C. Fernandes and Yushen Sun and Kai Xu and Sijie Sun and Sung Hoon Kang and Vincent Tournat and Katia Bertoldi},
url = {https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.118.084302},
doi = {10.1103/PhysRevLett.118.084302},
year = {2017},
date = {2017-02-21},
journal = {Physical Review Letters},
volume = {118},
pages = {084302},
abstract = {We demonstrate both numerically and experimentally that geometric frustration in two-dimensional periodic acoustic networks consisting of arrays of narrow air channels can be harnessed to form band gaps (ranges of frequency in which the waves cannot propagate in any direction through the system). While resonant standing wave modes and interferences are ubiquitous in all the analyzed network geometries, we show that they give rise to band gaps only in the geometrically frustrated ones (i.e., those comprising of triangles and pentagons). Our results not only reveal a new mechanism based on geometric frustration to suppress the propagation of pressure waves in specific frequency ranges but also open avenues for the design of a new generation of smart systems that control and manipulate sound and vibrations.},
keywords = {Acoustic, architected materials, Band gap, Geometrical Frustration, Metamaterial},
pubstate = {published},
tppubtype = {article}
}
We demonstrate both numerically and experimentally that geometric frustration in two-dimensional periodic acoustic networks consisting of arrays of narrow air channels can be harnessed to form band gaps (ranges of frequency in which the waves cannot propagate in any direction through the system). While resonant standing wave modes and interferences are ubiquitous in all the analyzed network geometries, we show that they give rise to band gaps only in the geometrically frustrated ones (i.e., those comprising of triangles and pentagons). Our results not only reveal a new mechanism based on geometric frustration to suppress the propagation of pressure waves in specific frequency ranges but also open avenues for the design of a new generation of smart systems that control and manipulate sound and vibrations.