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On circuits and subgraphs of chromatic graphs

Published online by Cambridge University Press:  26 February 2010

P. Erdös
Affiliation:
University College, London, W.C.I.
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Extract

A graph is said to be k-chromatic if its vertices can be split into k classes so that two vertices of the same class are not connected (by an edge) and such a splitting is not possible for k−1 classes. Tutte was the first to show that for every k there is a k-chromatic graph which contains no triangle [1].

Type
Research Article
Copyright
Copyright © University College London 1962

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References

1. Blanche Descartes, “A three colour problem”, Eureka (April 1947). Solution March 1948. See also Mycielski, J., “Sur le colorage des graphs”, Colloquium Math., 3 (1955), 161162CrossRefGoogle Scholar
2. Kelly, J. B. and Kelly, L. M., “Paths and circuits in critical graphs”, American J. of Math., 76 (1954), 786792.CrossRefGoogle Scholar
3. Erdös, P., “Graph theory and probability”, Canadian J. of Math., 11 (1959), 3438.CrossRefGoogle Scholar
4. Erdös, P. and Szekeres, G., “A combinatorial problem in geometry”, Comp. Math., 2 (1935), 463470.Google Scholar
5. Erdös, P. and Szekeres, G., “Graph theory and probability (II)”, Canadian J. of Math., 13 (1961), 346352.CrossRefGoogle Scholar
6. Erdös, P. and Rényi, A., “On the evolution of random graphs”, Pub. Mat. Inst. Hung. Acad., 5 (1960), 1761. See also the paper quoted in [3] and [5].Google Scholar