Further algorithmic aspects of the local lemma
STOC '98 Proceedings of the thirtieth annual ACM symposium on Theory of computing
Acyclic edge colorings of graphs
Journal of Graph Theory
Acyclic Edge Colouring of Outerplanar Graphs
AAIM '07 Proceedings of the 3rd international conference on Algorithmic Aspects in Information and Management
About acyclic edge colourings of planar graphs
Information Processing Letters
Acyclic edge coloring of graphs with maximum degree 4
Journal of Graph Theory
Acyclic edge chromatic number of outerplanar graphs
Journal of Graph Theory
Random Structures & Algorithms
Improved bounds on coloring of graphs
European Journal of Combinatorics
Acyclic Edge Coloring of Planar Graphs Without Small Cycles
Graphs and Combinatorics
Acyclic edge colouring of plane graphs
Discrete Applied Mathematics
Acyclic chromatic indices of fully subdivided graphs
Information Processing Letters
Optimal acyclic edge-coloring of cubic graphs
Journal of Graph Theory
Acyclic Edge Coloring of Triangle-Free Planar Graphs
Journal of Graph Theory
A new upper bound on the acyclic chromatic indices of planar graphs
European Journal of Combinatorics
The acyclic edge coloring of planar graphs without a 3-cycle adjacent to a 4-cycle
Discrete Applied Mathematics
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An acyclic edge coloring of a graph G is a proper edge coloring such that the subgraph induced by any two color classes is a linear forest (an acyclic graph with maximum degree at most two). The acyclic chromatic index@g"a^'(G) of a graph G is the least number of colors needed in an acyclic edge coloring of G. Fiamcik (1978) conjectured that @g"a^'(G)@?@D(G)+2, where @D(G) is the maximum degree of G. This conjecture is well known as the Acyclic Edge Coloring Conjecture (AECC). A graph G with maximum degree at most @k is @k-deletion-minimal if @g"a^'(G)@k and @g"a^'(H)@?@k for every proper subgraph H of G. The purpose of this paper is to provide many structural lemmas on @k-deletion-minimal graphs. By using the structural lemmas, we firstly prove that AECC is true for the graphs with maximum average degree less than four (Theorem 4.3). We secondly prove that AECC is true for the planar graphs without triangles adjacent to cycles of length at most four, with an additional condition that every 5-cycle has at most three edges contained in triangles (Theorem 4.4), from which we can conclude some known results as corollaries. We thirdly prove that every planar graph G without intersecting triangles satisfies @g"a^'(G)@?@D(G)+3 (Theorem 4.6). Finally, we consider one extreme case and prove it: if G is a graph with @D(G)=3 and all the 3^+-vertices are independent, then @g"a^'(G)=@D(G). We hope the structural lemmas will shed some light on the acyclic edge coloring problems.