The Petersen graph is the smallest snark.
The flower snark J5 is one of six snarks on 20 vertices.

In the mathematical field of graph theory, a snark is an undirected graph with exactly three edges per vertex whose edges cannot be colored with only three colors. In order to avoid trivial cases, snarks are often restricted to have additional requirements on their connectivity and on the length of their cycles. Infinitely many snarks exist.

One of the equivalent forms of the four color theorem is that every snark is a non-planar graph. Research on snarks originated in Peter G. Tait's work on the four color theorem in 1880, but their name is much newer, given to them by Martin Gardner in 1976. Beyond coloring, snarks also have connections to other hard problems in graph theory: writing in the Electronic Journal of Combinatorics, Miroslav Chladný and Martin Škoviera state that

In the study of various important and difficult problems in graph theory (such as the cycle double cover conjecture and the 5-flow conjecture), one encounters an interesting but somewhat mysterious variety of graphs called snarks. In spite of their simple definition...and over a century long investigation, their properties and structure are largely unknown.[1]

As well as the problems they mention, W. T. Tutte's snark conjecture concerns the existence of Petersen graphs as graph minors of snarks; its proof has been long announced but remains unpublished, and would settle a special case of the existence of nowhere zero 4-flows.

History and examples

Snarks were so named by the American mathematician Martin Gardner in 1976, after the mysterious and elusive object of the poem The Hunting of the Snark by Lewis Carroll.[2] However, the study of this class of graphs is significantly older than their name. Peter G. Tait initiated the study of snarks in 1880, when he proved that the four color theorem is equivalent to the statement that no snark is planar.[3] The first graph known to be a snark was the Petersen graph; it was proved to be a snark by Julius Petersen in 1898,[4] although it had already been studied for a different purpose by Alfred Kempe in 1886.[5]

The next four known snarks were

In 1975, Rufus Isaacs generalized Blanuša's method to construct two infinite families of snarks: the flower snarks and the Blanuša–Descartes–Szekeres snarks, a family that includes the two Blanuša snarks, the Descartes snark and the Szekeres snark. Isaacs also discovered a 30-vertex snark that does not belong to the Blanuša–Descartes–Szekeres family and that is not a flower snark: the double-star snark.[9] The 50-vertex Watkins snark was discovered in 1989.[10]

Another notable cubic non-three-edge-colorable graph is Tietze's graph, with 12 vertices; as Heinrich Franz Friedrich Tietze discovered in 1910, it forms the boundary of a subdivision of the Möbius strip requiring six colors.[11] However, because it contains a triangle, it is not generally considered a snark. Under strict definitions of snarks, the smallest snarks are the Petersen graph and Blanuša snarks, followed by six different 20-vertex snarks.[12]

A list of all of the snarks up to 36 vertices (according to a strict definition), and up to 34 vertices (under a weaker definition), was generated by Gunnar Brinkmann, Jan Goedgebeur, Jonas Hägglund and Klas Markström in 2012.[12] The number of snarks for a given even number of vertices grows at least exponentially in the number of vertices.[13] (Because they have odd-degree vertices, all snarks must have an even number of vertices by the handshaking lemma.)[14] OEIS sequence A130315 contains the number of non-trivial snarks of vertices for small values of .[15]

Definition

The precise definition of snarks varies among authors,[12][9] but generally refers to cubic graphs (having exactly three edges at each vertex) whose edges cannot be colored with only three colors. By Vizing's theorem, the number of colors needed for the edges of a cubic graph is either three ("class one" graphs) or four ("class two" graphs), so snarks are cubic graphs of class two. However, in order to avoid cases where a snark is of class two for trivial reasons, or is constructed in a trivial way from smaller graphs, additional restrictions on connectivity and cycle lengths are often imposed. In particular:

  • If a cubic graph has a bridge, an edge whose removal would disconnect it, then it cannot be of class one. By the handshaking lemma, the subgraphs on either side of the bridge have an odd number of vertices each. Whichever of three colors is chosen for the bridge, their odd number of vertices prevents these subgraphs from being covered by cycles that alternate between the other two colors, as would be necessary in a 3-edge-coloring. For this reason, snarks are generally required to be bridgeless.[2][9]
  • A loop (an edge connecting a vertex to itself) cannot be colored without causing the same color to appear twice at that vertex, a violation of the usual requirements for graph edge coloring. Additionally, a cycle consisting of two vertices connected by two edges can always be replaced by a single edge connecting their two other neighbors, simplifying the graph without changing its three-edge-colorability. For these reasons, snarks are generally restricted to simple graphs, graphs without loops or multiple adjacencies.[9]
  • If a graph contains a triangle, then it can again be simplified without changing its three-edge-colorability, by contracting the three vertices of the triangle into a single vertex. Therefore, many definitions of snarks forbid triangles.[9] However, although this requirement was also stated in Gardner's work giving the name "snark" to these graphs, Gardner lists Tietze's graph, which contains a triangle, as being a snark.[2]
  • If a graph contains a four-vertex cycle, it can be simplified in two different ways by removing two opposite edges of the cycle and replacing the resulting paths of degree-two vertices by single edges. It has a three-edge-coloring if and only if at least one of these simplifications does. Therefore, Isaacs requires a "nontrivial" cubic class-two graph to avoid four-vertex cycles,[9] and other authors have followed suit in forbidding these cycles.[12] The requirement that a snark avoid cycles of length four or less can be summarized by stating that the girth of these graphs, the length of their shortest cycles, is at least five.
  • More strongly, the definition used by Brinkmann et al. (2012) requires snarks to be cyclically 4-edge-connected. That means there can be no subset of three or fewer edges, the removal of which would disconnect the graph into two subgraphs each of which has at least one cycle. Brinkmann et al. define a snark to be a cubic and cyclically 4-edge-connected graph of girth five or more and class two; they define a "weak snark" to allow girth four.[12]

Although these definitions only consider constraints on the girth up to five, snarks with arbitrarily large girth exist.[16]

Properties

Work by Peter G. Tait established that the four-color theorem is true if and only if every snark is non-planar.[3] This theorem states that every planar graph has a graph coloring of its the vertices with four colors, but Tait showed how to convert 4-vertex-colorings of maximal planar graphs into 3-edge-colorings of their dual graphs, which are cubic and planar, and vice versa. A planar snark would therefore necessarily be dual to a counterexample to the four-color theorem. Thus, the subsequent proof of the four-color theorem[17] also demonstrates that all snarks are non-planar.[18]

All snarks are non-Hamiltonian: when a cubic graph has a Hamiltonian cycle, it is always possible to 3-color its edges, by using two colors in alternation for the cycle, and the third color for the remaining edges. However, many known snarks are close to being Hamiltonian, in the sense that they are hypohamiltonian graphs: the removal of any single vertex leaves a Hamiltonian subgraph. A hypohamiltonian snark must be bicritical: the removal of any two vertices leaves a three-edge-colorable subgraph.[19] The oddness of a cubic graph is defined as the minimum number of odd cycles, in any system of cycles that covers each vertex once (a 2-factor). For the same reason that they have no Hamiltonian cycles, snarks have positive oddness: a completely even 2-factor would lead to a 3-edge-coloring, and vice versa. It is possible to construct infinite families of snarks whose oddness grows linearly with their numbers of vertices.[14]

The cycle double cover conjecture posits that in every bridgeless graph one can find a collection of cycles covering each edge twice, or equivalently that the graph can be embedded onto a surface in such a way that all faces of the embedding are simple cycles. When a cubic graph has a 3-edge-coloring, it has a cycle double cover consisting of the cycles formed by each pair of colors. Therefore, among cubic graphs, the snarks are the only possible counterexamples. More generally, snarks form the difficult case for this conjecture: if it is true for snarks, it is true for all graphs.[20] In this connection, Branko Grünbaum conjectured that no snark could be embedded onto a surface in such a way that all faces are simple cycles and such that every two faces either are disjoint or share only a single edge; if any snark had such an embedding, its faces would form a cycle double cover. However, a counterexample to Grünbaum's conjecture was found by Martin Kochol.[21]

Determining whether a given cyclically 5-connected cubic graph is 3-edge-colorable is NP-complete. Therefore, determining whether a graph is a snark is co-NP-complete.[22]

Snark conjecture

W. T. Tutte conjectured that every snark has the Petersen graph as a minor. That is, he conjectured that the smallest snark, the Petersen graph, may be formed from any other snark by contracting some edges and deleting others. Equivalently (because the Petersen graph has maximum degree three) every snark has a subgraph that can be formed from the Petersen graph by subdividing some of its edges. This conjecture is a strengthened form of the four color theorem, because any graph containing the Petersen graph as a minor must be nonplanar. In 1999, Neil Robertson, Daniel P. Sanders, Paul Seymour, and Robin Thomas announced a proof of this conjecture.[23] Steps towards this result have been published,[24][25] but as of 2022, the complete proof remains unpublished.[18][24] See the Hadwiger conjecture for other problems and results relating graph coloring to graph minors.

Tutte also conjectured a generalization to arbitrary graphs: every bridgeless graph with no Petersen minor has a nowhere zero 4-flow. That is, the edges of the graph may be assigned a direction, and a number from the set {1, 2, 3}, such that the sum of the incoming numbers minus the sum of the outgoing numbers at each vertex is divisible by four. As Tutte showed, for cubic graphs such an assignment exists if and only if the edges can be colored by three colors, so the conjecture would follow from the snark conjecture in this case. However, proving the snark conjecture would not settle the question of the existence of 4-flows for non-cubic graphs.[26]

References

  1. Chladný, Miroslav; Škoviera, Martin (2010), "Factorisation of snarks", Electronic Journal of Combinatorics, 17: R32, doi:10.37236/304, MR 2595492
  2. 1 2 3 Gardner, Martin (1976), "Snarks, boojums, and other conjectures related to the four-color-map theorem", Mathematical Games, Scientific American, 4 (234): 126–130, Bibcode:1976SciAm.234d.126G, doi:10.1038/scientificamerican0476-126, JSTOR 24950334
  3. 1 2 Tait, Peter Guthrie (1880), "Remarks on the colourings of maps", Proceedings of the Royal Society of Edinburgh, 10: 729, doi:10.1017/S0370164600044643
  4. Petersen, Julius (1898), "Sur le théorème de Tait", L'Intermédiaire des Mathématiciens, 5: 225–227
  5. Kempe, A. B. (1886), "A memoir on the theory of mathematical form", Philosophical Transactions of the Royal Society of London, 177: 1–70, doi:10.1098/rstl.1886.0002, S2CID 108716533
  6. Blanuša, Danilo (1946), "Le problème des quatre couleurs", Glasnik Matematičko-Fizički i Astronomski, Ser. II, 1: 31–42, MR 0026310
  7. Descartes, Blanche (1948), "Network-colourings", The Mathematical Gazette, 32 (299): 67–69, doi:10.2307/3610702, JSTOR 3610702, MR 0026309, S2CID 250434686
  8. Szekeres, George (1973), "Polyhedral decompositions of cubic graphs", Bulletin of the Australian Mathematical Society, 8 (3): 367–387, doi:10.1017/S0004972700042660
  9. 1 2 3 4 5 6 Isaacs, Rufus (1975), "Infinite families of non-trivial trivalent graphs which are not Tait-colorable", The American Mathematical Monthly, 82 (3): 221–239, doi:10.2307/2319844, JSTOR 2319844
  10. Watkins, John J. (1989), "Snarks", in Capobianco, Michael F.; Guan, Mei Gu; Hsu, D. Frank; Tian, Feng (eds.), Graph theory and its Applications: East and West, Proceedings of the First China–USA International Conference held in Jinan, June 9–20, 1986, Annals of the New York Academy of Sciences, vol. 576, New York: New York Academy of Sciences, pp. 606–622, doi:10.1111/j.1749-6632.1989.tb16441.x, MR 1110857, S2CID 222072657
  11. Tietze, Heinrich (1910), "Einige Bemerkungen zum Problem des Kartenfärbens auf einseitigen Flächen" [Some remarks on the problem of map coloring on one-sided surfaces] (PDF), DMV Annual Report, 19: 155–159
  12. 1 2 3 4 5 Brinkmann, Gunnar; Goedgebeur, Jan; Hägglund, Jonas; Markström, Klas (2012), "Generation and properties of snarks", Journal of Combinatorial Theory, Series B, 103 (4): 468–488, arXiv:1206.6690, doi:10.1016/j.jctb.2013.05.001, MR 3071376, S2CID 15284747
  13. Skupień, Zdzisław (2007), "Exponentially many hypohamiltonian snarks", 6th Czech-Slovak International Symposium on Combinatorics, Graph Theory, Algorithms and Applications, Electronic Notes in Discrete Mathematics, vol. 28, pp. 417–424, doi:10.1016/j.endm.2007.01.059
  14. 1 2 Lukot'ka, Robert; Máčajová, Edita; Mazák, Ján; Škoviera, Martin (2015), "Small snarks with large oddness", Electronic Journal of Combinatorics, 22 (1), Paper 1.51, arXiv:1212.3641, doi:10.37236/3969, MR 3336565, S2CID 4805178
  15. Sloane, N. J. A. (ed.), "Sequence A130315", The On-Line Encyclopedia of Integer Sequences, OEIS Foundation
  16. Kochol, Martin (1996), "Snarks without small cycles", Journal of Combinatorial Theory, Series B, 67 (1): 34–47, doi:10.1006/jctb.1996.0032, MR 1385382
  17. Appel, Kenneth; Haken, Wolfgang (1989), Every Planar Map is Four-Colorable, Contemporary Mathematics, vol. 98, With the collaboration of J. Koch., Providence, RI: American Mathematical Society, doi:10.1090/conm/098, ISBN 0-8218-5103-9, MR 1025335, S2CID 8735627
  18. 1 2 belcastro, sarah-marie (2012), "The continuing saga of snarks", The College Mathematics Journal, 43 (1): 82–87, doi:10.4169/college.math.j.43.1.082, MR 2875562, S2CID 118189042
  19. Steffen, E. (1998), "Classification and characterizations of snarks", Discrete Mathematics, 188 (1–3): 183–203, doi:10.1016/S0012-365X(97)00255-0, MR 1630478; Steffen, E. (2001), "On bicritical snarks", Math. Slovaca, 51 (2): 141–150, MR 1841443
  20. Jaeger, François (1985), "A survey of the cycle double cover conjecture", in Alspach, B. R.; Godsil, C. D. (eds.), Annals of Discrete Mathematics 27: Cycles in Graphs, North-Holland Mathematics Studies, vol. 27, pp. 1–12, doi:10.1016/S0304-0208(08)72993-1, ISBN 978-0-444-87803-8
  21. Kochol, Martin (2009), "Polyhedral embeddings of snarks in orientable surfaces", Proceedings of the American Mathematical Society, vol. 137, pp. 1613–1619
  22. Kochol, Martin (2010), "Complexity of 3-edge-coloring in the class of cubic graphs with a polyhedral embedding in an orientable surface", Discrete Applied Mathematics, 158 (16): 1856–1860, doi:10.1016/j.dam.2010.06.019, MR 2679785
  23. Thomas, Robin (1999), "Recent excluded minor theorems for graphs" (PDF), Surveys in Combinatorics, 1999, Cambridge University Press, pp. 201–222
  24. 1 2 Edwards, Katherine; Sanders, Daniel P.; Seymour, Paul; Thomas, Robin (2016), "Three-edge-colouring doublecross cubic graphs" (PDF), Journal of Combinatorial Theory, Series B, 119: 66–95, doi:10.1016/j.jctb.2015.12.006, MR 3486338, S2CID 2656843
  25. Robertson, Neil; Seymour, Paul; Thomas, Robin (2019), "Excluded minors in cubic graphs", Journal of Combinatorial Theory, Series B, 138: 219–285, arXiv:1403.2118, doi:10.1016/j.jctb.2019.02.002, MR 3979232, S2CID 16237685
  26. DeVos, Matthew (March 7, 2007), "4-flow conjecture", Open Problem Garden
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.