Size scaling and stiffness of avian primary feathers: implications for the flight of Mesozoic birds
Size scaling and stiffness of avian primary feathers: implications for the flight of Mesozoic birds
The primary feathers of birds are subject to cyclical forces in flight causing their shafts (rachises) to bend. The amount the feathers deflect during flight is dependent upon the flexural stiffness of the rachises. By quantifying scaling relationships between body mass and feather linear dimensions in a large data set of living birds, we show that both feather length and feather diameter scale much closer to predictions for geometric similarity than they do to elastic similarity. Scaling allometry also indicates that the primary feathers of larger birds are relatively shorter and their rachises relatively narrower, compared to
those of smaller birds. Two-point bending tests indicated that larger birds have more flexible feathers than smaller species. Discriminant functional analyses (DFA) showed that body mass, primary feather length and rachis diameter can
be used to differentiate between different magnitudes of feather bending stiffness, with primary feather length explaining 63% of variance in rachis stiffness. Adding fossil measurement data to our DFA showed that Archaeopteryx
and Confuciusornis do not overlap with extant birds. This strongly suggests that the bending stiffness of their primary feathers was different to extant birds and provides further evidence for distinctive flight styles and likely limited flight ability in Archaeopteryx and Confuciusornis.
bending stiffness, birds, primary feathers, scaling
547-555
Wang, X.
976221d1-3004-409c-8640-715bedfc5d15
Nudds, R.L.
f9e7472c-b4b8-4d09-bff5-68720e554ac8
Palmer, C.
050ad5a2-9afa-45a2-b630-b1548680a029
Dyke, G.J.
600ca61e-b40b-4c86-b8ae-13be4e331e94
2012
Wang, X.
976221d1-3004-409c-8640-715bedfc5d15
Nudds, R.L.
f9e7472c-b4b8-4d09-bff5-68720e554ac8
Palmer, C.
050ad5a2-9afa-45a2-b630-b1548680a029
Dyke, G.J.
600ca61e-b40b-4c86-b8ae-13be4e331e94
Wang, X., Nudds, R.L., Palmer, C. and Dyke, G.J.
(2012)
Size scaling and stiffness of avian primary feathers: implications for the flight of Mesozoic birds.
Journal of Evolutionary Biology, 25 (3), .
(doi:10.1111/j.1420-9101.2011.02449.x).
Abstract
The primary feathers of birds are subject to cyclical forces in flight causing their shafts (rachises) to bend. The amount the feathers deflect during flight is dependent upon the flexural stiffness of the rachises. By quantifying scaling relationships between body mass and feather linear dimensions in a large data set of living birds, we show that both feather length and feather diameter scale much closer to predictions for geometric similarity than they do to elastic similarity. Scaling allometry also indicates that the primary feathers of larger birds are relatively shorter and their rachises relatively narrower, compared to
those of smaller birds. Two-point bending tests indicated that larger birds have more flexible feathers than smaller species. Discriminant functional analyses (DFA) showed that body mass, primary feather length and rachis diameter can
be used to differentiate between different magnitudes of feather bending stiffness, with primary feather length explaining 63% of variance in rachis stiffness. Adding fossil measurement data to our DFA showed that Archaeopteryx
and Confuciusornis do not overlap with extant birds. This strongly suggests that the bending stiffness of their primary feathers was different to extant birds and provides further evidence for distinctive flight styles and likely limited flight ability in Archaeopteryx and Confuciusornis.
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Published date: 2012
Keywords:
bending stiffness, birds, primary feathers, scaling
Organisations:
Ocean Biochemistry & Ecosystems
Identifiers
Local EPrints ID: 336370
URI: http://eprints.soton.ac.uk/id/eprint/336370
ISSN: 1010-061X
PURE UUID: f405598f-fcdf-4407-b6ae-cf610bb1d550
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Date deposited: 22 Mar 2012 11:23
Last modified: 14 Mar 2024 10:41
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Contributors
Author:
X. Wang
Author:
R.L. Nudds
Author:
C. Palmer
Author:
G.J. Dyke
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