Finally, a truly physical argument acknowledges that generating lift inevitably produces drag, at least in a viscous fluid. The deflection of air downward creates downstream vortices (lift-induced drag), and the boundary layer creates friction drag and pressure drag due to separation. Both processes increase entropy. A perfect, reversible lifting surface is impossible. The elegant potential flow solutions of textbooks are limiting cases; real aerodynamics is the physics of entropy generation, shear layers, and vorticity transport.
The most direct route to understanding lift comes from Newton’s Third Law: for every action, there is an equal and opposite reaction. An airfoil generates lift by deflecting air downward. The angle of attack forces the oncoming stream to change direction; the wing’s lower surface pushes air down and forward, while the upper surface, through curvature and angle, also directs air downward. According to Newton’s Second Law, changing the air’s vertical momentum requires a force. The wing exerts that downward force on the air, and the air exerts an equal upward force on the wing—lift. understanding aerodynamics arguing from the real physics pdf
This momentum-streamtube argument is rigorous: measure the vertical velocity imparted to a large volume of air far downstream, multiply by the mass flow rate, and you obtain the lift. No mysterious pressure imbalance appears out of nowhere; it emerges from the wing’s action on the flow. A perfect, reversible lifting surface is impossible