Cross-modulation in guided wave propagation: how does it relate to the Luxemburg-Gorky effect?

•A theoretical framework is proposed to study guided wave cross modulation.•The guided wave cross modulation is numerically and experimentally confirmed.•The relationship between guided wave cross modulation and l-G effect is analyzed. The well-known Luxemburg-Gorky effect in radio waves has also be...

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Bibliographic Details
Published in:Journal of sound and vibration 2024-01, Vol.568, p.117961, Article 117961
Main Authors: Shan, Shengbo, Zhang, Yuanman, Liu, Ze, Wen, Fuzhen, Cheng, Li, Staszewski, Wieslaw J
Format: Article
Language:English
Subjects:
Cross-modulation
Guided waves
Material nonlinearity
The Luxemburg-Gorky effect
Wave mixing
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Summary:•A theoretical framework is proposed to study guided wave cross modulation.•The guided wave cross modulation is numerically and experimentally confirmed.•The relationship between guided wave cross modulation and l-G effect is analyzed. The well-known Luxemburg-Gorky effect in radio waves has also been observed in elastic waves recently, which points to new possibilities for incipient damage detection. However, how the cross-modulation phenomenon of guided waves in a weakly nonlinear medium is related to the Luxemburg-Gorky effect remains an open question. This issue is investigated in this paper. Considering the third-order nonlinear elasticity of a plate waveguide, a theoretical framework is proposed to analyze the influence of the mode combination and mixing direction of a pair of single-frequency and modulated waves on the cross-modulated component generation. In particular, a codirectional shear-horizontal wave mixing scheme is highlighted which enables the generation of internally-resonant cross-modulated components at all frequencies. After verification by finite element simulation, mechanisms underpinning the cross-modulated components in the codirectional shear-horizontal wave mixing scheme are revealed through tactical tuning of the higher-order material elastic constants. Experiments are conducted to further confirm the phenomena and substantiate their relevance to the Luxemburg-Gorky effect. It is established that the cross-modulated components of guided waves can be generated and practically measured in a weakly nonlinear plate via both pure and mixed mechanisms as a result of the cubic nonlinearity instead of the quadratic nonlinearity. Compared with the conventional two-wave mixing methods based on quadratic nonlinearity, the cross-modulated components exhibit higher sensitivity to material microstructural changes, which is conducive to incipient damage detection. Although the observed nonlinear cross-modulation in guided waves shows similarities with the Luxemburg-Gorky effect, they stem from different mechanisms: the former from nonlinear elasticity and the latter nonlinear dissipation.
ISSN:0022-460X
1095-8568
DOI:10.1016/j.jsv.2023.117961