Friction plus compressibility of the finger pads are key to a speedy snap
It all happens in a snap. New high-speed video exposes the blink-and-you’ll-miss-it physics behind snapping your fingers.
The footage reveals the extreme speed at which the gesture occurs, and shows that friction plus the compressibility of the finger pads are key to humans’ ability to snap properly, researchers report November 17 in Journal of the Royal Society Interface.
Finger snaps last only about seven milliseconds — that’s roughly 20 times as fast as the blink of an eye, says biophysicist Saad Bhamla of Georgia Tech in Atlanta. After slipping off the thumb, the middle finger rotates at a rate up to 7.8 degrees per millisecond, nearly what a professional baseball pitcher’s arm can achieve, the team found. And a snapping finger accelerates almost three times as fast as pitchers’ arms.
When covered with high-friction rubber or low-friction lubricant, fingers made snaps that fell flat, the team found, indicating that bare fingers have a level of friction ideal for a speedy snap (SN: 8/1/19). That friction between the thumb and middle finger allows energy to be stored before it’s suddenly unleashed. Too little friction means less pent-up energy and a slower snap. But too much friction impedes the finger’s release, also slowing the snap.
Bhamla and colleagues were inspired by a scene in the 2018 movie Avengers: Infinity War. The supervillain Thanos snaps his fingers while wearing a supernatural metal glove, obliterating half of the universe’s life. The team wondered if it would be possible to snap while wearing a rigid glove. Typically, when the fingers press together in a snap, they compress, increasing the contact area and friction between them. So the researchers tested snapping with fingers covered by hard thimbles. Sure enough, the snaps were sluggish.
So Thanos’ snap would have been a dud. No superheroes needed: Physics saves the day.