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Biomechanics of a moth scale at ultrasonic frequencies

Research output: Contribution to journalArticle

Original languageEnglish
Pages (from-to)12200-12205
Number of pages6
JournalProceedings of the National Academy of Sciences of the United States of America
Volume115
Issue number48
Early online date12 Nov 2018
DOIs
DateAccepted/In press - 9 Oct 2018
DateE-pub ahead of print - 12 Nov 2018
DatePublished (current) - 27 Nov 2018

Abstract

The wings of moths and butterflies are densely covered in scales that exhibit intricate shapes and sculptured nanostructures. While certain butterfly scales create nanoscale photonic effects, moth scales show different nanostructures suggesting different functionality. Here we investigate moth-scale vibrodynamics to understand their role in creating acoustic camouflage against bat echolocation, where scales on wings provide ultrasound absorber functionality. For this, individual scales can be considered as building blocks with adapted biomechanical properties at ultrasonic frequencies. The 3D nanostructure of a full Bunaea alcinoe moth forewing scale was characterized using confocal microscopy. Structurally, this scale is double layered and endowed with different perforation rates on the upper and lower laminae, which are interconnected by trabeculae pillars. From these observations a parameterized model of the scale’s nanostructure was formed and its effective elastic stiffness matrix extracted. Macroscale numerical modeling of scale vibrodynamics showed close qualitative and quantitative agreement with scanning laser Doppler vibrometry measurement of this scale’s oscillations, suggesting that the governing biomechanics have been captured accurately. Importantly, this scale of B. alcinoe exhibits its first three resonances in the typical echolocation frequency range of bats, suggesting it has evolved as a resonant absorber. Damping coefficients of the moth-scale resonator and ultrasonic absorption of a scaled wing were estimated using numerical modeling. The calculated absorption coefficient of 0.50 agrees with the published maximum acoustic effect of wing scaling. Understanding scale vibroacoustic behavior helps create macroscopic structures with the capacity for broadband acoustic camouflage.

    Research areas

  • Acoustics, Moth scale, Porous materials, Ultrasonics, Vibration

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  • Full-text PDF (accepted author manuscript)

    Rights statement: This is the author accepted manuscript (AAM). The final published version (version of record) is available online via NAS at http://www.pnas.org/content/early/2018/11/06/1810025115 . Please refer to any applicable terms of use of the publisher.

    Accepted author manuscript, 716 KB, PDF-document

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