Check Out Nike’s Crazy New Machine-Designed Track Shoe
The Zoom Superfly Elite spike plate is all one piece; the spikes aren’t screwed in, like they are with traditional sprinting shoes. The webbed structure also defies any kind of grid or obvious unit of measurement. The cells seem to shrink and swarm around the outsides and arch of the foot, and expand around the ball and heel areas.
These almost alien looks are the result of more than four years of algorithmic software design and 3-D printing prototyping, done in the Nike Sports Research Lab. Before even the London Olympics, designers there have endeavored to create a track shoe with the lightest and stiffest spike plate ever made. With the Zoom Superfly Elite, created with help from Jamaican track star Shelly-Ann Fraser-Pryce, Nike says it’s done it. This plate is about half the weight—61 grams, down from 118—of the one on the Ja Fly 2, Nike’s last spike. It’s also four times as stiff.
If you’re a sprinter, stiffness if your friend. In 2000, researchers at the University of Calgary’s Human Performance Lab found that a stiff outsole reduces the amount of energy lost at the metatarsophalangeal joint (where the pad of your foot meets the base of your toe), which improves an athlete’s efficiency during sprinting and jumping. In a followup study, researchers from the lab found that increasing the stiffness of an athlete’s shoe lead to a boost in sprinting performance.
But stiffness isn’t the only thing you have to consider when designing a track shoe. According to Bret Schoolmeester, innovation director at Nike Running, adding stiffness to something as featherlight as a pair of track spikes typically results in a heavier shoe. The stiffer=faster equation breaks down when the benefits of a shoe’s stiffness are outweighed by its… well, its weight. If the shoe is too heavy, it doesn’t matter how stiff it is; it’s going to slow the athlete down.
Bedeviled by the tradeoff between weight and stiffness, Nike designers turned to computational design. Computational (aka generative, or algorithmic) design is an ideal way to create lighter, stronger structures. Software can easily take the goals of the problem—stiffness and lightness—and optimize for both, whereas a human would likely design by altering an existing shoe. In the Nike Sports Research Lab, designers captured heat maps of Pryce as she ran the 100-meter dash. They fed that data into an algorithm, which translated it into a spike plate optimized for weight and rigidity. They 3-D printed prototypes and tested them, repeating the cycle until they had a design that could really perform.
So far, Nike’s gotten results in the lab. When Pryce wore the Zoom Superfly Elite shoes, she slashed her 100-meter-dash time by 0.148 seconds. That might not seem like much (it’s less time than it takes you to blink), but Pryce’s margin of victory at the London Olympics was 0.03 seconds. “It’s an unbelievable performance advantage,” Schoolmeester says. “That [0.148 seconds] is enough to take you from off the podium to the top of it.”