Chiral polytope

This article is about polytopes with full rotational symmetry. For polytopes lacking mirror symmetry see, see Chirality.

In the study of abstract polytopes, a chiral polytope is that it is a polytope that is as symmetric as possible without being mirror-symmetric, formalized in terms of the action of the symmetry group of the polytope on its flags.

The flags of Heawood map under its automorphism group form two orbits, colored here in black and yellow.

Definition

The more technical definition of a chiral polytope is a polytope that has two orbits of flags under its group of symmetries, with adjacent flags in different orbits. This implies that it must be vertex-transitive, edge-transitive, and face-transitive, as each vertex, edge, or face must be represented by flags in both orbits; however, it cannot be mirror-symmetric, as every mirror symmetry of the polytope would exchange some pair of adjacent flags.^[1]

For the purposes of this definition, the symmetry group of a polytope may be defined in either of two different ways: it can refer to the symmetries of a polytope as a geometric object (in which case the polytope is called geometrically chiral) or it can refer to the symmetries of the polytope as a combinatorial structure (the automorphisms of an abstract polytope). Chirality is meaningful for either type of symmetry but the two definitions classify different polytopes as being chiral or nonchiral.^[2]

Geometrically chiral polytopes

Geometrically chiral polytopes are relatively exotic compared to the more ordinary regular polytopes. It is not possible for a geometrically chiral polytope to be convex,^[3] and many geometrically chiral polytopes of note are skew.

In three dimensions

In three dimensions, it is not possible for a geometrically chiral polytope to have finitely many finite faces. For instance, the snub cube is vertex-transitive, but its flags have more than two orbits, and it is neither edge-transitive nor face-transitive, so it is not symmetric enough to meet the formal definition of chirality. The quasiregular polyhedra and their duals, such as the cuboctahedron and the rhombic dodecahedron, provide another interesting type of near-miss: they have two orbits of flags, but are mirror-symmetric, and not every adjacent pair of flags belongs to different orbits. However, despite the nonexistence of finite chiral three-dimensional polyhedra, there exist infinite three-dimensional chiral skew polyhedra of types {4,6}, {6,4}, and {6,6}.^[2]

In four dimensions

In four dimensions, there are a geometrically chiral finite polytopes. One example is Roli's cube, a skew polytope on the skeleton of the 4-cube.^[4][5]

References

1. Schulte, Egon; Weiss, Asia Ivić (1991), "Chiral polytopes", in Gritzmann, P.; Sturmfels, B. (eds.), Applied Geometry and Discrete Mathematics (The Victor Klee Festschrift), DIMACS Series in Discrete Mathematics and Theoretical Computer Science, vol. 4, Providence, RI: American Mathematical Society, pp. 493–516, MR 1116373.
2. Schulte, Egon (2004), "Chiral polyhedra in ordinary space. I", Discrete and Computational Geometry, 32 (1): 55–99, doi:10.1007/s00454-004-0843-x, MR 2060817, S2CID 13098983.
3. Pellicer, Daniel (2012). "Developments and open problems on chiral polytopes". Ars Mathematica Contemporanea. 5 (2): 333–354. doi:10.26493/1855-3974.183.8a2.
4. Bracho, Javier; Hubard, Isabel; Pellicer, Daniel (2014), "A Finite Chiral 4-polytope in ℝ⁴", Discrete Computational Geometry
5. Monson, Barry (2021), On Roli's Cube, arXiv:2102.08796

Further reading

• Monson, Barry; Pisanski, Tomaž; Schulte, Egon; Weiss, Asia Ivić (2007), "Semisymmetric graphs from polytopes", Journal of Combinatorial Theory, Series A, 114 (3): 421–435, arXiv:math/0606469, doi:10.1016/j.jcta.2006.06.007, MR 2310743, S2CID 10203794.
• Hubard, Isabel; Weiss, Asia Ivić (2005), "Self-duality of chiral polytopes", Journal of Combinatorial Theory, Series A, 111 (1): 128–136, doi:10.1016/j.jcta.2004.11.012, MR 2144859.
• Conder, Marston; Hubard, Isabel; Pisanski, Tomaž (2008), "Constructions for chiral polytopes", Journal of the London Mathematical Society, Second Series, 77 (1): 115–129, doi:10.1112/jlms/jdm093, MR 2389920, S2CID 14658184.
• Monson, Barry; Ivić Weiss, Asia (2008), "Cayley graphs and symmetric 4-polytopes", Ars Mathematica Contemporanea, 1 (2): 185–205, doi:10.26493/1855-3974.79.919, MR 2466196.