The role of wings in early birds is typically interpreted through the lens of flight, yet Archaeopteryx was also a terrestrial predator that pursued prey on the ground. This paper proposes a novel mechanism, described using a detailed terrestrial biomechanics analysis, by which bilateral flapping motion could have directly enhanced prey capture during a rapid, ground-based lunge. This biomechanics description provides detailed biomechanical analyses over a 0.6‑second complex sequence of events that could have occurred during the pursuit of prey animals. The forces described include the initiation of an upstroke that generates a downward aerodynamic reaction force that, combined with gravity, pitches the center of mass forward and eccentrically loads the hind limbs, triggering a stretch‑shortening cycle. A subsequent downstroke provides lift to prevent premature ground contact of the whole body while generating forward thrust, and a final leg extension delivers the jaws of Archaeopteryx to the prey. This mechanism integrates known principles of avian biomechanics, angular momentum, and neuromuscular reflexes into a simple, testable hypothesis. I present this not as a complete explanation of Archaeopteryx wing utilization behavior, but as one piece of the complex puzzle describing how Archaeopteryx used its wings in a terrestrial context—shifting focus from aerial performance to terrestrial utility, and inviting further empirical and modeling studies.
Charles Darryl Potts (Tue,) studied this question.