In geometry, the Gosset–Elte figures, named by Coxeter after Thorold Gosset and E. L. Elte, are a group of uniform polytopes which are not regular, generated by a Wythoff construction with mirrors all related by order-2 and order-3 dihedral angles. They can be seen as one-end-ringedCoxeter–Dynkin diagrams. The Coxeter symbol for these figures has the form ki,j, where each letter represents a length of order-3 branches on a Coxeter–Dynkin diagram with a single ring on the end node of a k length sequence of branches. The vertex figure of ki,j is i,j, and each of its facets are represented by subtracting one from one of the nonzero subscripts, i.e. ki − 1,j and ki,j − 1. Rectified simplices are included in the list as limiting cases with k=0. Similarly 0i,j,k represents a bifurcated graph with a central node ringed.
History
named these figures as ki,j in shorthand and gave credit of their discovery to Gosset and Elte:
Thorold Gosset first publisheda list of regular and semi-regular figures in space of n dimensions in 1900, enumerating polytopes with one or more types of regular polytope faces. This included the rectified 5-cell021 in 4-space, demipenteract121 in 5-space, 221 in 6-space, 321 in 7-space, 421 in 8-space, and 521 infinite tessellation in 8-space.
E. L. Elte independently enumerated a different semiregular list in his 1912 book, The Semiregular Polytopes of the Hyperspaces. He called them semiregular polytopes of the first kind, limiting his search to one or two types of regular or semiregular k-faces.
Elte's enumeration included all the kij polytopes except for the 142 which has 3 types of 6-faces. The set of figures extend into honeycombs of,, and families in 6,7,8 dimensional Euclidean spaces respectively. Gosset's list included the 521honeycomb as the only semiregular one in his definition.
Definition
The polytopes and honeycombs in this family can be seen within ADE classification. A finite polytopekij exists if or equal for Euclidean honeycombs, and less for hyperbolic honeycombs. The Coxeter group can generate up to 3 unique uniform Gosset–Elte figures with Coxeter–Dynkin diagrams with one end node ringed. By Coxeter's notation, each figure is represented by kij to mean the end-node on the k-length sequence is ringed. The simplex family can be seen as a limiting case with k=0, and all rectified Coxeter–Dynkin diagrams.
The family of n-simplices contain Gosset–Elte figures of the form 0ij as all rectified forms of the n-simplex. They are listed below, along with their Coxeter–Dynkin diagram, with each dimensional family drawn as a graphic orthogonal projection in the plane of the Petrie polygon of the regular simplex.
Each Dn group has two Gosset–Elte figures, the n-demihypercube as 1k1, and an alternated form of the n-orthoplex, k11, constructed with alternating simplex facets. Rectified n-demihypercubes, a lower symmetry form of a birectified n-cube, can also be represented as 0k11.
Each En group from 4 to 8 has two or three Gosset–Elte figures, represented by one of the end-nodes ringed:k21, 1k2, 2k1. A rectified 1k2 series can also be represented as 0k21.
2k1
1k2
k21
0k21
E4
= 201
= 120
= 021
E5
= 211
= 121
= 121
= 0211
E6
= 221
= 122
= 221
= 0221
E7
= 231
= 132
= 321
= 0321
E8
= 241
= 142
= 421
= 0421
Euclidean and hyperbolic honeycombs
There are three Euclidean Coxeter groups in dimensions 6, 7, and 8: There are three hyperbolic Coxeter groups in dimensions 7, 8, and 9: As a generalization more order-3 branches can also be expressed in this symbol. The 4-dimensional affine Coxeter group,, , has four order-3 branches, and can express one honeycomb, 1111,, represents a lower symmetry form of the 16-cell honeycomb, and 01111, for the rectified 16-cell honeycomb. The 5-dimensional hyperbolic Coxeter group,, , has five order-3 branches, and can express one honeycomb, 11111, and its rectification as 011111,.
