The chromatic number of the square of the 8-cube

Kokkala, Janne; Östergård, Patric

doi:10.1090/mcom/3291

The chromatic number of the square of the $8$-cube
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by Janne I. Kokkala and Patric R. J. Östergård PDF

Math. Comp. 87 (2018), 2551-2561 Request permission

Abstract:

A cube-like graph is a Cayley graph for the elementary abelian group of order $2^n$. In studies of the chromatic number of cube-like graphs, the $k$th power of the $n$-dimensional hypercube, $Q_n^k$, is frequently considered. This coloring problem can be considered in the framework of coding theory, as the graph $Q_n^k$ can be constructed with one vertex for each binary word of length $n$ and edges between vertices exactly when the Hamming distance between the corresponding words is at most $k$. Consequently, a proper coloring of $Q_n^k$ corresponds to a partition of the $n$-dimensional binary Hamming space into codes with minimum distance at least $k+1$. The smallest open case, the chromatic number of $Q_8^2$, is here settled by finding a 13-coloring. Such 13-colorings with specific symmetries are further classified.

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