2008
DOI: 10.1007/s10910-008-9471-7
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Fullerene graphs have exponentially many perfect matchings

Abstract: A fullerene graph is a planar cubic 3-connected graph with only pentagonal and hexagonal faces. We show that fullerene graphs have exponentially many perfect matchings.Comment: 7 pages, 3 figure

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Cited by 31 publications
(27 citation statements)
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“…However, the assignment of double bonds (Kekul e structures) to fullerenes is equivalent in graph theory to finding perfect matchings, [18] of which fullerene graphs have exponentially many. [19] While the exponential theoretical lower bound for the number of perfect matchings in fullerenes only kicks in at C 380 , the rapid growth in their numbers starts much sooner: The IPR fullerene I h -C 60 (I h -C 70 ) has as many as 12,500 (52,168) Kekul e structures, of which 158 (2780) are nonisomorphic. [20,21] As this number grows, searching through all Kekul e structures for the most stable one becomes impractical, and force fields for fullerenes should, therefore, not be designed with double bonds in mind.…”
Section: Introductionmentioning
confidence: 99%
“…However, the assignment of double bonds (Kekul e structures) to fullerenes is equivalent in graph theory to finding perfect matchings, [18] of which fullerene graphs have exponentially many. [19] While the exponential theoretical lower bound for the number of perfect matchings in fullerenes only kicks in at C 380 , the rapid growth in their numbers starts much sooner: The IPR fullerene I h -C 60 (I h -C 70 ) has as many as 12,500 (52,168) Kekul e structures, of which 158 (2780) are nonisomorphic. [20,21] As this number grows, searching through all Kekul e structures for the most stable one becomes impractical, and force fields for fullerenes should, therefore, not be designed with double bonds in mind.…”
Section: Introductionmentioning
confidence: 99%
“…We refer the reader to [11] for an exposition of this connection and of an elegant proof of Gurvits generalizing Schrijver's result. For fullerene graphs, a class of planar cubic graphs for which the conjecture relates to molecular stability and aromaticity of fullerene molecules, the problem was settled by Kardoš, Král', Miškuf and Sereni [9]. Chudnovsky and Seymour recently proved the conjecture for all cubic bridgeless planar graphs [1].…”
Section: Introductionmentioning
confidence: 99%
“…Proof. In [11], it was proven that for every fullerene graph G on n vertices there is a decomposition of its edges into three perfect matchings M 1 , M 2 , M 3 , such that at least one of them, say M 1 , has at least n−380 61 resonant hexagons. Then G ′ = M 2 ∪ M 3 is a 2-factor of the graph G having at least n−380 61 shifts.…”
Section: Search For a Good Startmentioning
confidence: 99%