Add to ORKGBasal birds such as Archaeopteryx and Confuciusornis are typically portrayed as flapping fliers. However, here I show that shoulder joint orientation in these animals prevented elevation of the humerus above the dorsum, thereby preventing use of the recovery stroke, an important part of flapping flight. In members of the clade Ornithothoraces, which includes extant birds and the extinct avian clade Enantiornithes, the shoulder joint is reoriented to permit elevation of the humerus above the dorsum, permitting flapping flight. Although basal birds may have glided, flapping flight began significantly later in avian evolution than has been thought
In the past many authors have focused on the anatomical study of the wing in order to correlate anat...
Birds still share many traits with their dinosaur ancestors, making them the best living group to re...
Past studies have shown that birds use their wings not only for flight, but also when ascending stee...
Background: Powered flight is implicated as a major driver for the success of birds. Here we examine...
Ontogenetic and behavioral studies using birds currently do not document the early evolution of flig...
Background. Powered flight is implicated as a major driver for the success of birds. Here we examine...
Past studies have shown that birds use their wings not only for flight, but also when ascending stee...
<div><p>Past studies have shown that birds use their wings not only for flight, but also when ascend...
Theropod dinosaurs show striking morphological and functional tail variation; e.g., a long, robust, ...
Powered flight evolved three times independently among tetrapods (Pterosauria, Aves, Chiroptera), ea...
<div><p>Theropod dinosaurs show striking morphological and functional tail variation; e.g., a long, ...
<div><p>Birds still share many traits with their dinosaur ancestors, making them the best living gro...
Background The origin of powered avian flight was a locomotor innovation that expanded the ecologica...
Theropod dinosaurs show striking morphological and functional tail variation; e.g., a long, robust, ...
The functional anatomies of avian finger joints have never been compared with those of the basal avi...
In the past many authors have focused on the anatomical study of the wing in order to correlate anat...
Birds still share many traits with their dinosaur ancestors, making them the best living group to re...
Past studies have shown that birds use their wings not only for flight, but also when ascending stee...
Background: Powered flight is implicated as a major driver for the success of birds. Here we examine...
Ontogenetic and behavioral studies using birds currently do not document the early evolution of flig...
Background. Powered flight is implicated as a major driver for the success of birds. Here we examine...
Past studies have shown that birds use their wings not only for flight, but also when ascending stee...
<div><p>Past studies have shown that birds use their wings not only for flight, but also when ascend...
Theropod dinosaurs show striking morphological and functional tail variation; e.g., a long, robust, ...
Powered flight evolved three times independently among tetrapods (Pterosauria, Aves, Chiroptera), ea...
<div><p>Theropod dinosaurs show striking morphological and functional tail variation; e.g., a long, ...
<div><p>Birds still share many traits with their dinosaur ancestors, making them the best living gro...
Background The origin of powered avian flight was a locomotor innovation that expanded the ecologica...
Theropod dinosaurs show striking morphological and functional tail variation; e.g., a long, robust, ...
The functional anatomies of avian finger joints have never been compared with those of the basal avi...
In the past many authors have focused on the anatomical study of the wing in order to correlate anat...
Birds still share many traits with their dinosaur ancestors, making them the best living group to re...
Past studies have shown that birds use their wings not only for flight, but also when ascending stee...