Some new results on Sylvester colorings of cubic graphs
Abstract
If G and H are two cubic multi-graphs, then an H-coloring of G is a mapping f: E(G)→ E(H), such that for every v∈ V(G) there is a vertex x∈ V(H), such that f(∂G(v))=∂H(x). If G admits an H-coloring then it is common to write H G. The Petersen coloring conjecture predicts that for any bridgeless cubic graph G one has P10 G. Here P10 is the Petersen graph. Let f: E(G)→ E(H) be any mapping. Define: V(f)=\v∈ V(G):∃ x∈ V(H), f(∂G(v))=∂H(x)\. Let S10 be the smallest cubic multi-graph that has no perfect matching. It has ten vertices. Define S12 as the cubic graph that is obtained from S10, by replacing its unique vertex z adjacent to three bridges with a triangle. In this paper we show that (1) for every cubic multi-graph G with a perfect matching, there is a mapping f:E(G)→ E(S12), such that |V(f)|≥ 45· |V(G)|, and (2) for every cubic multi-graph G, there is a mapping f:E(G)→ E(S10), such that |V(f)|≥ 56· |V(G)|. Our second result improves the 45-bound by Hakobyan and the second author from 2018.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.