Abstract
We consider cell colorings of drawings of graphs in the plane. Given a multi-graph $G$ together with a drawing $\Gamma(G)$ in the plane with only finitely many crossings, we define a cell $k$-coloring of $\Gamma(G)$ to be a coloring of the maximal connected regions of the drawing, the cells, with $k$ colors such that adjacent cells have different colors. By the $4$-color theorem, every drawing of a bridgeless graph has a cell $4$-coloring. A drawing of a graph is cell $2$-colorable if and only if the underlying graph is Eulerian. We show that every graph without degree 1 vertices admits a cell $3$-colorable drawing. This leads to the natural question which abstract graphs have the property that each of their drawings has a cell $3$-coloring. We say that such a graph is universally cell $3$-colorable. We show that every $4$-edge-connected graph and every graph admitting a nowhere-zero $3$-flow is universally cell $3$-colorable. We also discuss circumstances under which universal cell $3$-colorability guarantees the existence of a nowhere-zero $3$-flow. On the negative side, we present an infinite family of universally cell $3$-colorable graphs without a nowhere-zero $3-flow. On the positive side, we formulate a conjecture which has a surprising relation to a famous open problem by Tutte known as the $3$-flow-conjecture. We prove our conjecture for subcubic and for $K_{3,3}$-minor-free graphs.
Highlights
Graph coloring is one of the earliest and most influential branches of graph theory, whose first occurences date back more than 150 years
This problem was resolved in the positive in 1972 when Appel and Haken [2, 3] presented a computer-assisted proof of their famous 4-Color-Theorem, which formally states that the chromatic number of every planar graph is at most 4
In this paper we combine the topics of graph coloring and graph drawing by studying colorings of planar maps arising from drawings1 of possibly non-planar graphs
Summary
Graph coloring is one of the earliest and most influential branches of graph theory, whose first occurences date back more than 150 years. From Theorem 4 and Theorem 5 we can see that a planar graph is universally cell 3colorable if and only if it admits a nowhere zero 3-flow. This has the following interesting consequence regarding the computational complexity of recognising universally cell 3colorable graphs.
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