In geometry, the GossetâÂÂElte 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-ringed CoxeterâÂÂDynkin diagrams.
The Coxeter symbol for these figures has the form k<sub>i,j</sub>, where each letter represents a length of order-3 branches on a CoxeterâÂÂDynkin diagram with a single ring on the end node of a k length sequence of branches. The vertex figure of k<sub>i,j</sub> is (k − 1)<sub>i,j</sub>, and each of its facets are represented by subtracting one from one of the nonzero subscripts, i.e. k<sub>i − 1,j</sub> and k<sub>i,j − 1</sub>.
Rectified simplices are included in the list as limiting cases with k=0. Similarly 0<sub>i,j,k</sub> represents a bifurcated graph with a central node ringed.
Coxeter named these figures as k<sub>i,j</sub> (or k<sub>ij</sub>) in shorthand and gave credit of their discovery to Gosset and Elte:
Elte's enumeration included all the k<sub>ij</sub> polytopes except for the 1<sub>42</sub> which has 3 types of 6-faces.
The set of figures extend into honeycombs of (2,2,2), (3,3,1), and (5,4,1) families in 6,7,8 dimensional Euclidean spaces respectively. Gosset's list included the 5<sub>21</sub> honeycomb as the only semiregular one in his definition.
The polytopes and honeycombs in this family can be seen within ADE classification.
A finite polytope k<sub>ij</sub> exists if
or equal for Euclidean honeycombs, and less for hyperbolic honeycombs.
The Coxeter group [3<sup>i,j,k</sup>] can generate up to 3 unique uniform GossetâÂÂElte figures with CoxeterâÂÂDynkin diagrams with one end node ringed. By Coxeter's notation, each figure is represented by k<sub>ij</sub> 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 (single-ring) CoxeterâÂÂDynkin diagrams.
The family of n-simplices contain GossetâÂÂElte figures of the form 0<sub>ij</sub> as all rectified forms of the n-simplex (i + j = n − 1).
They are listed below, along with their CoxeterâÂÂDynkin diagram, with each dimensional family drawn as a graphic orthogonal projection in the plane of the Petrie polygon of the regular simplex.
Each D<sub>n</sub> group has two GossetâÂÂElte figures, the n-demihypercube as 1<sub>k1</sub>, and an alternated form of the n-orthoplex, k<sub>11</sub>, constructed with alternating simplex facets. Rectified n-demihypercubes, a lower symmetry form of a birectified n-cube, can also be represented as 0<sub>k11</sub>.
Each E<sub>n</sub> group from 4 to 8 has two or three GossetâÂÂElte figures, represented by one of the end-nodes ringed:k<sub>21</sub>, 1<sub>k2</sub>, 2<sub>k1</sub>. A rectified 1<sub>k2</sub> series can also be represented as 0<sub>k21</sub>.
There are three Euclidean (affine) Coxeter groups in dimensions 6, 7, and 8:
There are three hyperbolic (paracompact) 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, , [3<sup>1,1,1,1</sup>], has four order-3 branches, and can express one honeycomb, 1<sub>111</sub>, , represents a lower symmetry form of the 16-cell honeycomb, and 0<sub>1111</sub>, for the rectified 16-cell honeycomb. The 5-dimensional hyperbolic Coxeter group, , [3<sup>1,1,1,1,1</sup>], has five order-3 branches, and can express one honeycomb, 1<sub>1111</sub>, and its rectification as 0<sub>11111</sub>, .