Frucht theorem

In 1938, R. Frucht [a1] affirmatively answered a question posed by D. König [a2], by proving that every abstract group is isomorphic to the automorphism group of some graph (cf. also Graph automorphism). This is know as Frucht's theorem. In 1949, Frucht [a3] extended this result by showing that for every abstract group $\Gamma$ there is a $3$-regular graph whose automorphism group is isomorphic to $\Gamma$.

For a proof of these results see [a4]. For an alternative proof of Frucht's theorem see [a5].

G. Sabidussi [a6] further extended this result by proving that, given an abstract group $\Gamma$, there is a graph $G$ with automorphism group isomorphic to $\Gamma$ and such that $G$ has a prescribed vertex connectivity, a prescribed chromatic number, or is $k$-regular for a given integer $k$, or has a spanning subgraph $\widetilde H$ homeomorphic to a given connected graph $H$.

These investigations have led to the study of graphical regular representations of groups. A graphical regular representation of a given abstract group $\Gamma$ is a graph $G$ whose automorphism group acts regularly on its vertex set and is isomorphic to $\Gamma$. A sample reference is [a7].

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