From Lee Sallows:

(Thanks, Lee!)

This figure contains four “cliques” of four points each, with each of the four points in each clique connected to each of the others, and each pair of cliques intersecting at a single point. Four colors suffice to color all the points so that no two linked points share a color.

Is this always possible? If k cliques, each containing k points, are arranged in similar fashion, can the result always be colored properly with k colors? In 2021, half a century after Paul Erdős first posed the question, Dong Yeap Kang and his colleagues proved that, for sufficiently large k, the conjecture is true.

The Wallace–Bolyai–Gerwien theorem, first proven in 1807, states that any two polygons of equal area must have a common dissection. That is, there’s always a way to cut up the first one and assemble the pieces to form the second.

But what if the pieces must be connected by hinges? In his “haberdasher” puzzle of 1907, Henry Dudeney showed that it’s possible to convert a triangle into a square by cutting it in pieces and turning it “inside out”:

Is it always possible to arrange such a “hinged dissection” between two polygons of equal area? The question remained open until 2007, when Erik Demaine showed that the answer is yes — and provided an algorithm to find it.

02/25/2026 UPDATE: Reader Simon Schneider directed me to this interactive visualization of the Wallace–Bolyai–Gerwien theorem, which lets you draw two polygons and then converts one to the other before your eyes. It’s hypnotizing. Here’s a paper on the dissection algorithm used. (Thanks, Simon.)

The numbers 1-7 are disposed among the regions in this figure such that each of the circular sets yields the same sum. This makes it a “magic Venn diagram,” a concept that occurred to mathematician David Robinson while teaching a course in mathematical logic at the University of West Georgia. His article appears in the December 2025 issue of Recreational Mathematics Magazine.

(David Robinson and Anja Remshagen, “Magic Venn Diagrams,” Recreational Mathematics Magazine 12:21 [December 2025], 25-44.)

We tend to think that mirrors reverse left to right, but in fact they reverse “back to front,” along an axis perpendicular to the mirror’s surface. Our confusion arises when we misinterpret this.

“[I]magine a back-front reversal of yourself, with your nose, face, eyes, and so forth pushed through to the back of the head, and your back somehow oozed through to the front,” writes University of Auckland psychologist Michael C. Corballis. “You might then ‘feel’ your watch as having remained on the left wrist (say), while back and front have reversed. However it is likely that you will also experience a strong compulsion to recalibrate your internal axes, and then feel the watch to be on the right wrist. In short, a back-front reversal is reinterpreted as a left-right reversal.”

(Michael C. Corballis, “Much Ado About Mirrors,” Psychonomic Bulletin & Review 7:1 [2000], 163-169. More mirror puzzles.)

It’s been known since 1882 that it’s impossible to construct a square with the area of a given circle using only a compass and straightedge.

But in 1977 Thomas Elsner showed that the task becomes possible if the circle is allowed to roll: