You find a strategy you think is going to work, but at some point, you run into a dead end. With infinite tiles, you begin laying down pieces. You have to follow one rule, however: the edges of the tiles are colored, and only same-colored edges can touch. Suppose you want to tile an infinite surface with an infinite number of square tiles. Can you create an infinite mosaic with only same-color edges touching? Credit: Anomie/Wikimedia But such beauty harbors unanswerable questions-ones that are, as mathematician Robert Berger stated in 1966, provably unprovable. From Beautiful Patterns to Unprovable QuestionsĪnyone who has walked through the breathtaking mosaic corridors of the palace Alhambra in Granada, Spain, knows the artistry involved in tiling a plane. The team recently reported its results in a paper that was posted to the preprint server and has not yet been peer-reviewed. Even better, they found that Smith had discovered not only one but an infinite number of einstein tiles. Together with software developer Joseph Samuel Myers and mathematician Chaim Goodman-Strauss of the University of Arkansas, Kaplan proved that Smith’s singular tile does indeed pave the plane without gaps and without repetition. When he told Craig Kaplan, a computer scientist at the University of Waterloo in Ontario, Kaplan quickly recognized the potential of the shape. He discovered a 13-sided, craggy shape that he believed could be an einstein tile. Then, last November, retired printing systems engineer David Smith of Yorkshire, England, had a breakthrough. Many mathematicians had already given up hope of finding a solution with one tile, called the elusive “einstein” tile, which gets its name from the German words for “one stone.” Until now, aperiodic tilings always required at least two tiles of different shapes. No matter how you chop up the mosaic, each section will be unique. In these special cases, called aperiodic tilings, there’s no pattern that you can copy and paste to keep the tiling going. Specifically, mathematicians are interested in tile shapes that can cover the whole plane without ever creating a repeating design. For centuries, experts have been studying the special properties of tile shapes that can cover floors, kitchen backsplashes or infinitely large planes without leaving any gaps. It is also one of the hardest problems in mathematics. Creatively tiling a bathroom floor isn’t just a stressful task for DIY home renovators.
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