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Wing–antenna interaction reduces odour fatigue in butterfly odour-tracking flight

Zhipeng Lou, Menglong Lei, Haibo Dong, Chengyu Li

2024Journal of Fluid Mechanics12 citationsDOIOpen Access PDF

Abstract

Flying insects exhibit remarkable capabilities in coordinating their olfactory sensory system and flapping wings during odour plume-tracking flights. While observations have indicated that their flapping wing motion can ‘sniff’ up the incoming plumes for better odour sampling range, how flapping motion impacts the odour concentration field around the antennae is unknown. Here, we reconstruct the body and wing kinematics of a forwards-flying butterfly based on high-speed images. Using an in-house computational fluid dynamics solver, we simulate the unsteady flow field and odourant transport process by solving the Navier–Stokes and odourant advection-diffusion equations. Our results show that, during flapping flight, the interaction between wing leading-edge vortices and antenna vortices strengthens the circulation of antenna vortices by over two-fold compared with cases without flapping motion, leading to a significant increase in odour intensity fluctuation along the antennae. Specifically, the interaction between the wings and antennae amplifies odour intensity fluctuations on the antennae by up to 8.4 fold. This enhancement is critical in preventing odour fatigue during odour-tracking flights. Further analysis reveals that this interaction is influenced by the inter-antennal angle. Adjusting this angle allows insects to balance between resistance to odour fatigue and the breadth of odour sampling. Narrower inter-antennal angles enhance fatigue resistance, while wider angles extend the sampling range but reduce resistance. Additionally, our findings suggest that while the flexibility of the wings and the thorax's pitching motion in butterflies do influence odour fluctuation, their impact is relatively secondary to that of the wing–antenna interaction.

Topics & Concepts

WingButterflyAcousticsAntenna (radio)Computer scienceButterfly valveMarine engineeringEnvironmental scienceAerospace engineeringPhysicsStructural engineeringBiologyTelecommunicationsEcologyEngineeringBiomimetic flight and propulsion mechanismsNeurobiology and Insect Physiology ResearchInsect Pheromone Research and Control
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