Article Synopsis
- Previous explanations for why nocturnal insects fly erratically around lights included theories like "lunar navigation" and "escape to the light," but these claims lacked rigorous testing due to the absence of 3D flight data.
- Using advanced motion capture and stereo-videography techniques, researchers found that insects do not fly directly toward the light; instead, they turn their dorsum (back) toward the light, resulting in flight paths that are perpendicular to the light source.
- The study suggests that the insects' instinct to tilt their dorsum toward bright light helps maintain flight control, but near artificial lights, this reaction leads to erratic steering and traps them, explaining their unusual behavior.
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Article Abstract
Explanations of why nocturnal insects fly erratically around fires and lamps have included theories of "lunar navigation" and "escape to the light". However, without three-dimensional flight data to test them rigorously, the cause for this odd behaviour has remained unsolved. We employed high-resolution motion capture in the laboratory and stereo-videography in the field to reconstruct the 3D kinematics of insect flights around artificial lights. Contrary to the expectation of attraction, insects do not steer directly toward the light. Instead, insects turn their dorsum toward the light, generating flight bouts perpendicular to the source. Under natural sky light, tilting the dorsum towards the brightest visual hemisphere helps maintain proper flight attitude and control. Near artificial sources, however, this highly conserved dorsal-light-response can produce continuous steering around the light and trap an insect. Our guidance model demonstrates that this dorsal tilting is sufficient to create the seemingly erratic flight paths of insects near lights and is the most plausible model for why flying insects gather at artificial lights.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10827719 | PMC |
| http://dx.doi.org/10.1038/s41467-024-44785-3 | DOI Listing |
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