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The well-known Steinberg's conjecture asserts that any planar graph without 4- and 5-cycles is 3 colorable. In this note we have given a short algorithmic proof of this conjecture based on the spiral chains of planar graphs proposed in the…

Combinatorics · Mathematics 2007-05-23 I. Cahit

Listed as No. 53 among the one hundred famous unsolved problems in [J. A. Bondy, U. S. R. Murty, Graph Theory, Springer, Berlin, 2008] is Steinberg's conjecture, which states that every planar graph without 4- and 5-cycles is 3-colorable.…

Combinatorics · Mathematics 2017-02-27 Ligang Jin , Yingli Kang , Michael Schubert , Yingqian Wang

It was conjectured by Steinberg in 1976 that planar graphs without cycles of length 4 or 5 are 3-colorable. This conjecture attracted a substantial amount of attention and was finally refuted by Cohen-Addad, Hebdige, Kr\'{a}l', Li and…

Combinatorics · Mathematics 2025-11-18 Xiaoyan Xu , Xuding Zhu

In the first partial result toward Steinberg's now-disproved three coloring conjecture, Abbott and Zhou used a counting argument to show that every planar graph without cycles of lengths 4 through 11 is 3-colorable. Implicit in their proof…

Combinatorics · Mathematics 2022-09-13 Zachary Hamaker , Vincent Vatter

A graph is $(c_1, c_2, ..., c_k)$-colorable if the vertex set can be partitioned into $k$ sets $V_1,V_2, ..., V_k$, such that for every $i: 1\leq i\leq k$ the subgraph $G[V_i]$ has maximum degree at most $c_i$. We show that every planar…

Combinatorics · Mathematics 2012-08-17 Owen Hill , Gexin Yu

A graph $G$ is $(d_1,d_2,d_3)$-colorable if the vertex set $V(G)$ can be partitioned into three subsets $V_1,V_2$ and $V_3$ such that for $i\in\{1,2,3\}$, the induced graph $G[V_i]$ has maximum vertex-degree at most $d_i$. So,…

Combinatorics · Mathematics 2020-01-03 Ligang Jin , Yingli Kang , Peipei Liu , Yingqian Wang

A graph G is (a:b)-colorable if there exists an assignment of b-element subsets of {1,...,a} to vertices of G such that sets assigned to adjacent vertices are disjoint. We show that every planar graph without cycles of length 4 or 5 is…

Combinatorics · Mathematics 2019-07-16 Zdeněk Dvořák , Xiaolan Hu

Let G be a graph. It was proved that if G is a planar graph without {4, 6, 7}-cycles and without two 5-cycles sharing exactly one edge, then G 3-colorable. We observed that the proof of this result is not correct.

Combinatorics · Mathematics 2008-10-21 S. Akbari , Behrooz Bagheri Gh

In this paper, we prove that planar graphs without cycles of length 4, 6, 9 are 3-colorable.

Combinatorics · Mathematics 2017-02-27 Yingli Kang , Ligang Jin , Yingqian Wang

This paper proves that every planar graph without cycles of length 4, 7, or 9 is DP-3-colorable.

Combinatorics · Mathematics 2023-03-09 Yingli Kang , Ligang Jin , Xuding Zhu

In 1976, Steinberg conjectured that planar graphs without $4$-cycles and $5$-cycles are $3$-colorable. This conjecture attracted numerous researchers for about 40 years, until it was recently disproved by Cohen-Addad et al. (2017). However,…

Combinatorics · Mathematics 2020-03-24 Eun-Kyung Cho , Ilkyoo Choi , Boram Park

Two cycles are {\em adjacent} if they have an edge in common. Suppose that $G$ is a planar graph, for any two adjacent cycles $C_{1}$ and $C_{2}$, we have $|C_{1}| + |C_{2}| \geq 11$, in particular, when $|C_{1}| = 5$, $|C_{2}| \geq 7$. We…

Combinatorics · Mathematics 2010-04-06 Tao Wang

Say a graph $G$ is a {\em pentagraph} if every cycle has length at least five, and every induced cycle of odd length has length five. N. Robertson proposed the conjecture that the Petersen graph is the only pentagraph that is…

Combinatorics · Mathematics 2022-02-01 Maria Chudnovsky , Paul Seymour

The chromatic number of an planar graph is not greater than four and this is known by the famous four color theorem and is equal to two when the planar graph is bipartite. When the planar graph is even-triangulated or all cycles are greater…

Combinatorics · Mathematics 2009-01-20 I. Cahit

An acyclic edge coloring of a graph $G$ is a proper edge coloring such that no bichromatic cycles are produced. The acyclic edge coloring conjecture by Fiam{\v{c}}ik (1978) and Alon, Sudakov and Zaks (2001) states that every simple graph…

Discrete Mathematics · Computer Science 2020-05-14 Qiaojun Shu , Guohui Lin , Eiji Miyano

We prove the conjecture made by G.Wegner in 1977 that the square of every planar, cubic graph is $7$-colorable. Here, $7$ cannot be replaced by $6$.

Combinatorics · Mathematics 2017-08-16 Carsten Thomassen

Deciding whether a planar graph (even of maximum degree $4$) is $3$-colorable is NP-complete. Determining subclasses of planar graphs being $3$-colorable has a long history, but since Gr\"{o}tzsch's result that triangle-free planar graphs…

Combinatorics · Mathematics 2020-05-15 François Dross , Borut Lužar , Mária Maceková , Roman Soták

DP-coloring as a generalization of list coloring was introduced by Dvo\v{r}\'{a}k and Postle in 2017, who proved that every planar graph without cycles from 4 to 8 is 3-choosable, which was conjectured by Borodin {\it et al.} in 2007. In…

Combinatorics · Mathematics 2019-07-17 Runrun Liu , Xiangwen Li

Hu and Li investigate the signed graph version of Erd$\ddot{\mathrm{o}}$s problem: Is there a constant $c$ such that every signed planar graph without $k$-cycles, where $4\leq k\leq c$, is $3$-colorable and prove that each signed planar…

Combinatorics · Mathematics 2022-05-04 Lan Kaiyang , Liu Feng

In 1972, Mader showed that every graph without a 3-connected subgraph is 4-degenerate and thus 5-colorable}. We show that the number 5 of colors can be replaced by 4, which is best possible.

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