Their slow flight and the variable geometry of their wings also enabled pterosaurs to land very gently, reducing the chance of breaking their paper- thin bones. This helps to explain how they were able to become the largest flying animals ever known.
Using his 40 years of experience in the engineering industry, Colin Palmer constructed models of pterosaur wing sections from thin, curved sheets of epoxy resin/carbon fibre composite and tested them in a wind tunnel. These tests quantified the two-dimensional characteristics of pterosaur wings for the first time, showing that such creatures were significantly less aerodynamically efficient and were capable of flying at lower speeds than previously thought.
Colin Palmer said: “Pterosaur wings were adapted to a low-speed flight regime that minimizes sink rate. This regime is unsuited to marine style dynamic soaring adopted by many seabirds which requires high flight speed coupled with high aerodynamic efficiency, but is well suited to thermal/slope soaring. The low sink rate would have allowed pterosaurs to use the relatively weak thermal lift found over the sea.
“Since the bones of pterosaurs were thin-walled and thus highly susceptible to impact damage, the low-speed landing capability would have made an important contribution to avoiding injury and so helped to enable pterosaurs to attain much larger sizes than extant birds. The trade-off would have been an extreme vulnerability to strong winds and turbulence, both in flight and on the ground, like that experienced by modern-day paragliders.”
The research is published today in Proceedings of the Royal Society B.
Colin Palmer is an engineer by training, originally in ship science. An interest in what makes sailing vessels go led him to study low speed aerodynamics and the performance of thin airfoils. He is now applying this background to the analysis of vertebrate flight, focussing on large pterosaurs for his PhD. Using a combination of wind tunnel and vortex-lattice theoretical modelling, he aims to understand how pterosaur wings performed. Working with students in the Department of Aerospace Engineering, he will also undertake more sophisticated aerodynamic analysis using computational fluid dynamics. He ultimately wants to put all this information together to create a free-flying model of a pterosaur.
Paper
Flight in slow motion: aerodynamics of the pterosaur wing by Colin Palmer in Proceedings of the Royal Society B
Image
For further information about the image of a pterosaur used on this page, visit Ontograph Studios Ltd.