Colorings with only rainbow arithmetic progressions

Abstract: If we want to color $1,2,\ldots,n$ with the property that all 3-term arithmetic progressions are rainbow (that is, their elements receive 3 distinct colors), then, obviously, we need to use at least $n/2$ colors. Surprisingly, much fewer colors suffice if we are allowed to leave a negligible proportion of integers uncolored. Specifically, we prove that there exist $\alpha,\beta<1$ such that for every $n$, there is a subset $A$ of ${1,2,\ldots,n}$ of size at least $n-n^{\alpha}$, the elements of which can be colored with $n^{\beta}$ colors with the property that every 3-term arithmetic progression in $A$ is rainbow. Moreover, $\beta$ can be chosen to be arbitrarily small. Our result can be easily extended to $k$-term arithmetic progressions for any $k\ge 3$. As a corollary, we obtain the following result of Alon, Moitra, and Sudakov, which can be used to design efficient communication protocols over shared directional multi-channels. There exist $\alpha',\beta'<1$ such that for every $n$, there is a graph with $n$ vertices and at least $\binom{n}{2}-n^{1+\alpha'}$ edges, whose edge set can be partitioned into at most $n^{1+\beta'}$ induced matchings.