In the mathematical field of graph theory, the Wagner graph is a 3-regular graph with 8 vertices and 12 edges. It is the 8-vertex Möbius ladder graph.

As a Möbius ladder, the Wagner graph is nonplanar but has crossing number one, making it an apex graph. It can be embedded without crossings on a torus or projective plane, so it is also a toroidal graph. It has girth 4, diameter 2, radius 2, chromatic number 3, chromatic index 3 and is both 3-vertex-connected and 3-edge-connected.

The Wagner graph has 392 spanning trees; it and the complete bipartite graph K_3,3 have the most spanning trees among all cubic graphs with the same number of vertices.

The Wagner graph is a vertex-transitive graph but is not edge-transitive. Its full automorphism group is isomorphic to the dihedral group D₈ of order 16, the group of symmetries of an octagon, including both rotations and reflections.

The characteristic polynomial of the Wagner graph is

It is the only graph with this characteristic polynomial, making it a graph determined by its spectrum.

The Wagner graph is triangle-free and has independence number three, providing one half of the proof that the Ramsey number R(3,4) (the least number n such that any n-vertex graph contains either a triangle or a four-vertex independent set) is 9.

Möbius ladders play an important role in the theory of graph minors. The earliest result of this type is a 1937 theorem of Klaus Wagner (part of a cluster of results known as Wagner's theorem) that graphs with no K₅ minor can be formed by using clique-sum operations to combine planar graphs and the Möbius ladder M₈. For this reason M₈ is called the Wagner graph.