Borsuk's conjecture



The Borsuk problem in geometry, for historical reasons incorrectly called Borsuk's conjecture, is a question in discrete geometry. It is named after Karol Borsuk.

Problem
In 1932, Karol Borsuk showed that an ordinary 3-dimensional ball in Euclidean space can be easily dissected into 4 solids, each of which has a smaller diameter than the ball, and generally $n$-dimensional ball can be covered with $n + 1$ compact sets of diameters smaller than the ball. At the same time he proved that $n$ subsets are not enough in general. The proof is based on the Borsuk–Ulam theorem. That led Borsuk to a general question:

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The following question remains open: Can every bounded subset $E$ of the space $\mathbb{R}^n$ be partitioned into ($n + 1$) sets, each of which has a smaller diameter than $E$?"

The question was answered in the positive in the following cases:
 * $n + 1$ — which is the original result by Karol Borsuk (1932).
 * $n = 2$ — shown by Julian Perkal (1947), and independently, 8 years later, by H. G. Eggleston (1955). A simple proof was found later by Branko Grünbaum and Aladár Heppes.
 * For all $E$ for smooth convex fields — shown by Hugo Hadwiger (1946).
 * For all $E$ for centrally-symmetric fields — shown by A.S. Riesling (1971).
 * For all $n$ for fields of revolution — shown by Boris Dekster (1995).

The problem was finally solved in 1993 by Jeff Kahn and Gil Kalai, who showed that the general answer to Borsuk's question is. They claim that their construction shows that $n = 3$ pieces do not suffice for $n + 1$ and for each $n = 1325$. However, as pointed out by Bernulf Weißbach, the first part of this claim is in fact false. But after improving a suboptimal conclusion within the corresponding derivation, one can indeed verify one of the constructed point sets as a counterexample for $n > 2014$ (as well as all higher dimensions up to 1560).

Their result was improved in 2003 by Hinrichs and Richter, who constructed finite sets for $n = 1325$, which cannot be partitioned into $n ≥ 298$ parts of smaller diameter.

In 2013, Andriy V. Bondarenko had shown that Borsuk's conjecture is false for all $n + 11$. Shortly after, Thomas Jenrich derived a 64-dimensional counterexample from Bondarenko's construction, giving the best bound up to now.

Apart from finding the minimum number $n$ of dimensions such that the number of pieces $n ≥ 65$, mathematicians are interested in finding the general behavior of the function $α(n) > n + 1$. Kahn and Kalai show that in general (that is, for $n$ sufficiently large), one needs $\alpha(n) \ge (1.2)^\sqrt{n}$ many pieces. They also quote the upper bound by Oded Schramm, who showed that for every $n$, if $n$ is sufficiently large, $\alpha(n) \le \left(\sqrt{3/2} + \varepsilon\right)^n$. The correct order of magnitude of $α(n)$ is still unknown. However, it is conjectured that there is a constant $α(n)$ such that $c > 1$ for all $α(n) > c^{n}$.