The Joy of Why What Can Tiling Patterns Teach Us?
Jul 3, 2024
Discover the intriguing world of tiling patterns and a groundbreaking amateur who unveiled an aperiodic monotile. Explore the mathematical foundations and relationships between tessellations and natural structures, such as quasicrystals. Dive into the collaborative spirit of tiling enthusiasts and how their creativity thrives outside traditional academia. Uncover the intersection of mathematics and art through aperiodic tessellations, revealing beauty in complex geometric combinations. This journey highlights the unexpected ways math connects to our cosmos.
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Crystallographic Restriction on Tilings
- Periodic tilings of a plane can only have two-, three-, four-, or six-fold rotational symmetry due to the crystallographic restriction.
- Shapes like pentagons or octagons can't tile periodically with allowed rotational symmetries because their angles don't fit properly.
Wang Tiles and Decidability
- The decidability of whether a set of Wang tiles tiles the plane depends on whether all such sets that tile can tile periodically.
- Aperiodic tile sets proved this to be false, showing some tile sets only tile non-periodically, which complicates tiling algorithms.
Quasicrystals Link Math and Chemistry
- The discovery of quasicrystals by Daniel Schechtman in 1982 mirrored patterns in Penrose tilings, linking math to physical materials.
- This finding showed non-periodic, highly ordered atomic structures in real crystals, earning him a Nobel Prize in chemistry.