Circular colorings and acyclic choosability of graphs

Roussel, Nicolas

23 December 2009

Abstract: This thesis studies five kinds of graph colorings: the circular coloring, the total coloring, the (d; 1)-total labeling, the circular (r; 1)-total labeling, and the acyclic list coloring. We give upper bounds on the circular chromatic number of graphs with small maximum average degree, mad for short. It is proved that if mad(G)<22=9 then G has a 11=4-circular coloring, if mad(G) < 5=2 then G has a 14=5-circular coloring. A conjecture by Behzad and Vizing implies that £G+2 colors are always sufficient for a total coloring of graphs with maximum degree £G. The only open case for planar graphs is for £G = 6. Let G be a planar in which no vertex is contained in cycles of all lengths between 3 and 8. If £G(G) = 6, then G is total 8-colorable. If £G(G) = 8, then G is total 9-colorable. Havet and Yu [23] conjectured that every subcubic graph G ̸=K4 has (2; 1)-total number at most 5. We confirm the conjecture for graphs with maximum average degree less than 7=3 and for flower snarks. We introduce the circular (r; 1)-total labeling. As a relaxation of the aforementioned conjecture, we conjecture that every subcubic graph has circular (2; 1)-total number at most 7. We confirm the conjecture for graphs with maximum average degree less than 5=2. We prove that every planar graph with no cycles of lengths 4, 7 and 8 is acyclically 4-choosable. Combined with recent results, this implies that every planar graph with no cycles of length 4;k; l with 5 6 k < l 6 8 is acyclically 4-choosable.

Circular coloring

total coloring

missing cycles

maximum average degree

planar graphs

acyclic choosability

circular (r;1)-total labeling

(d;1)-total labeling