Alexander's Horned Sphere is one of the more frustrating fractals out there. It is a fractal, it's a ring, it's an endless series of branches, and, technically, it's a ball. At least, inside it is. Outside, well, the entire oddity of the Horned Sphere is to change how we define 'inside' and 'outside.'

If you ever need a wedding ring for a math nerd, you might want to look into a very patient jeweler who can make a convincing version of Alexander's Horned Sphere. The jeweler could never make a perfect version, but that's because the Horned Sphere is a fractal, an infinitely repeating pattern. The best way to picture making the Horned Ring is looking at your hands. Bring your finger and thumb close, like you're almost making an 'okay' gesture. Stop a bit before they touch. From the side of each fingertip sprout two little branches that curve towards the branches on the other hand. So another circle, perpendicular to the one that your fingers are making, is almost completed. Just before those branches touch, two more little branches spring from the side of each of those little branches, and almost make another perpendicular circle, and so on. It never ends.

The Horned Sphere is used as an example of 'pathological' or 'wild' math, because of a seemingly paradoxical property. It's called a Horned *Sphere* because its insides behave like a sphere. Looking at the video, you can see it being stretched out of a sphere, and theoretically, every Horned Sphere could be pushed back into a ball. Everything 'inside' a Horned Sphere is inside one big, continuous, self-contained space.

All right, what happens when you try to put a rubber band around a sphere? You're in for a challenge, because an elastic band will slip on, and then slip right off. There is one continuous inside of a sphere and there is one continuous outside of a sphere as well. It's easy to slip a band on and off of it. Now imagine trying to put a rubber band on a horned sphere. It can't be done, nor can a rubber band be slipped off the outside of the sphere without being broken. Other fractals occupy decimal dimensions or are seemingly solid shapes that are actually all surface area - this fractal can divide the world into one single spherical 'inside' but more than one 'outside.'

Getting just a little crazier, this is only even conceptually possible in a three dimensional universe. The Jordan Curve Theorem, showed that there is no single, enclosed curve that cannot carve a two-dimensional plane into an inside and an outside that mirror each other. It's only in the universe that we perceive that things can get more complicated than that. It's only in our reality that one spherical inside creating more than one outsides is possible.

Via Wolfram Math World, Duke, and The Math Book.

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