Physical laws explain why most flies evolved similar flight, with mosquitoes as outliers

Why most flies fly alike
High-resolution stacked image of the blowfly wing and thorax. The translucent wing attaches via an intricate hinge system to the muscular thorax that powers rapid wingbeats. Credit: Carlos Faulquier

A new study in PLOS Biology of 133 species of flies, mosquitoes and their relatives shows that most species fly in surprisingly similar ways. Physical and aerodynamic laws shape the evolution of their flight behavior more strongly than previously thought. Mosquitoes prove to be a striking exception.

Searching for patterns in insect flight

To better understand how dipterans fly, the researchers carried out the first large-scale comparative analysis of flight behavior across this group. Body and wing characteristics were mapped for 133 species. In addition, detailed flight measurements and aerodynamic analyses were conducted for 46 species.

"Much research on insect flight focuses on a single species at a time," says Florian Muijres, professor of experimental zoology at Wageningen University. "It is like shining a torch into a dark room: you only see a small part of the whole picture. By comparing dozens of species, we were able to turn on the light and for the first time see the full picture, thereby identifying patterns that apply across the entire group."

The comparison revealed a striking result: In most dipterans, wing movements and flight aerodynamics are surprisingly similar. The physical constraints of flapping flight force evolution into a narrow range of optimal solutions. Despite the enormous diversity in ecology and body form, most dipterans share the same aerodynamic blueprint.

Mosquitoes are the exception

One important exception breaks this rule: mosquitoes. These insects beat their wings at extremely high frequencies—up to 1,000 times per second—resulting in highly inefficient flight: around three times less efficient than that of fruit flies of comparable size.

"Many mosquitoes mate in dense swarms in the air, where their characteristic buzzing sound plays an important role," says researcher Ilam Bharathi. "Our results indicate that their wingbeats are adapted not only for aerodynamic performance, but also for acoustic communication. In that sense, a mosquito's flight resembles an insect version of a peacock's tail: energetically costly, but important for finding a mate."

The physics behind evolution

These findings help explain how physical constraints and evolutionary pressures shape animal flight. In addition, the efficient flight strategies observed in many flies may inspire future drones. A better understanding of the acoustic biology of mosquitoes may also provide new leads for research into the control of disease-transmitting species. Sound plays an important role in finding a mate, meaning that disrupting these signals could offer new ways of disrupting their reproduction.

Publication details

Camille Le Roy et al, Dipteran flight diversity is shaped by aerodynamic constraints, scaling, and evolutionary trade-offs, PLOS Biology (2026). DOI: 10.1371/journal.pbio.3003473

Who's behind this story?

Lisa Lock

Lisa Lock

BA art history, MA material culture. Former museum editor, paramedic, and transplant coordinator. Editing for Science X since 2021. Full profile →

Andrew Zinin

Andrew Zinin

Master's in physics with research experience. Long-time science news enthusiast. Plays key role in Science X's editorial success. Full profile →

Citation: Physical laws explain why most flies evolved similar flight, with mosquitoes as outliers (2026, July 10) retrieved 11 July 2026 from https://phys.org/news/2026-07-physical-laws-flies-evolved-similar.html

This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.