Runcinated 24-cells


24-cell

Runcinated 24-cell

Runcitruncated 24-cell

Omnitruncated 24-cell
(Runcicantitruncated 24-cell)
Orthogonal projections in F4 Coxeter plane

In four-dimensional geometry, a runcinated 24-cell is a convex uniform 4-polytope, being a runcination (a 3rd order truncation) of the regular 24-cell.

There are 3 unique degrees of runcinations of the 24-cell including with permutations truncations and cantellations.

Runcinated 24-cell

Runcinated 24-cell
Type Uniform 4-polytope
Schläfli symbol t0,3{3,4,3}
Coxeter diagram
Cells 240 48 3.3.3.3
192 3.4.4
Faces 672 384{3}
288{4}
Edges 576
Vertices 144
Vertex figure
elongated square antiprism
Symmetry group Aut(F4), [[3,4,3]], order 2304
Properties convex, edge-transitive
Uniform index 25 26 27

In geometry, the runcinated 24-cell or small prismatotetracontoctachoron is a uniform 4-polytope bounded by 48 octahedra and 192 triangular prisms. The octahedral cells correspond with the cells of a 24-cell and its dual.

E. L. Elte identified it in 1912 as a semiregular polytope.

Coordinates

The Cartesian coordinates of the runcinated 24-cell having edge length 2 is given by all permutations of sign and coordinates of:

(0, 0, √2, 2+√2)
(1, 1, 1+√2, 1+√2)

The permutations of the second set of coordinates coincide with the vertices of an inscribed cantellated tesseract.

Projections

orthographic projections
Coxeter plane F4 B4
Graph
Dihedral symmetry [[12]] = [24] [8]
Coxeter plane B3 / A2 B2 / A3
Graph
Dihedral symmetry [6] [[4]] = [8]
3D perspective projections

Schlegel diagram, centered on octahedron, with the octahedra shown.

Perspective projection of the runcinated 24-cell into 3 dimensions, centered on an octahedral cell.

The rotation is only of the 3D image, in order to show its structure, not a rotation in 4-space. Fifteen of the octahedral cells facing the 4D viewpoint are shown here in red. The gaps between them are filled up by a framework of triangular prisms.


Stereographic projection with 24 of its 48 octahedral cells

Related regular skew polyhedron

The regular skew polyhedron, {4,8|3}, exists in 4-space with 8 square around each vertex, in a zig-zagging nonplanar vertex figure. These square faces can be seen on the runcinated 24-cell, using all 576 edges and 288 vertices. The 384 triangular faces of the runcinated 24-cell can be seen as removed. The dual regular skew polyhedron, {8,4|3}, is similarly related to the octagonal faces of the bitruncated 24-cell.

Runcitruncated 24-cell

Runcitruncated 24-cell
Type Uniform 4-polytope
Schläfli symbol t0,1,3{3,4,3}
s2,3{3,4,3}
Coxeter diagram
Cells 240 24 4.6.6
96 4.4.6
96 3.4.4
24 3.4.4.4
Faces 1104 192{3}
720{4}
192{6}
Edges 1440
Vertices 576
Vertex figure
Trapezoidal pyramid
Symmetry group F4, [3,4,3], order 1152
Properties convex
Uniform index 28 29 30

The runcitruncated 24-cell or prismatorhombated icositetrachoron is a uniform 4-polytope derived from the 24-cell. It is bounded by 24 truncated octahedra, corresponding with the cells of a 24-cell, 24 rhombicuboctahedra, corresponding with the cells of the dual 24-cell, 96 triangular prisms, and 96 hexagonal prisms.

Coordinates

The Cartesian coordinates of an origin-centered runcitruncated 24-cell having edge length 2 are given by all permutations of coordinates and sign of:

(0, √2, 2√2, 2+3√2)
(1, 1+√2, 1+2√2, 1+3√2)

The permutations of the second set of coordinates give the vertices of an inscribed omnitruncated tesseract.

The dual configuration has coordinates generated from all permutations and signs of:

(1,1,1+√2,5+√2)
(1,3,3+√2,3+√2)
(2,2,2+√2,4+√2)

Projections

orthographic projections
Coxeter plane F4
Graph
Dihedral symmetry [12]
Coxeter plane B3 / A2 (a) B3 / A2 (b)
Graph
Dihedral symmetry [6] [6]
Coxeter plane B4 B2 / A3
Graph
Dihedral symmetry [8] [4]

Schlegel diagram
centered on rhombicuboctahedron
only triangular prisms shown

Runcicantic snub 24-cell

A half-symmetry construction of the runcitruncated 24-cell (or runcicantellated 24-cell), as , also called a runcicantic snub 24-cell, as , has an identical geometry, but its triangular faces are further subdivided. Like the snub 24-cell, it has symmetry [3+,4,3], order 576. The runcitruncated 24-cell has 192 identical hexagonal faces, while the runcicantic snub 24-cell has 2 constructive sets of 96 hexagons. The difference can be seen in the vertex figures:



Runcic snub 24-cell

Runcic snub 24-cell
Schläfli symbol s3{3,4,3}
Coxeter diagram
Cells 240 24 {3,5}
24 t{3,3}
96 (4.4.3)
96 tricup
Faces 960 576 {3}
288 {4}
96 {6}
Edges 1008
Vertices 288
Vertex figure
Symmetry group [3+,4,3], order 576
Properties convex

A related 4-polytope is the runcic snub 24-cell or prismatorhombisnub icositetrachoron, s3{3,4,3}, . It is not uniform, but it is vertex-transitive and has all regular polygon faces. It is constructed with 24 icosahedra, 24 truncated tetrahedra, 96 triangular prisms, and 96 triangular cupolae in the gaps, for a total of 240 cells, 960 faces, 1008 edges, and 288 vertices. Like the snub 24-cell, it has symmetry [3+,4,3], order 576.[1]

The vertex figure contains one icosahedron, two triangular prisms, one truncated tetrahedron, and 3 triangular cupolae.

Orthographic projections Net

Omnitruncated 24-cell

Omnitruncated 24-cell
Type Uniform 4-polytope
Schläfli symbol t0,1,2,3{3,4,3}
Coxeter diagram
Cells 240 48 (4.6.8)
192 (4.4.6)
Faces 1392 864{4}
384{6}
144{8}
Edges 2304
Vertices 1152
Vertex figure
Phyllic disphenoid
Symmetry group Aut(F4), [[3,4,3]], order 2304
Properties convex
Uniform index 29 30 31

The omnitruncated 24-cell or great prismatotetracontoctachoron is a uniform 4-polytope derived from the 24-cell. It is composed of 1152 vertices, 2304 edges, and 1392 faces (864 squares, 384 hexagons, and 144 octagons). It has 240 cells: 48 truncated cuboctahedra, 192 hexagonal prisms. Each vertex contains four cells in an irregular tetrahedral vertex figure: two hexagonal prisms, and two truncated cuboctahedra.

Structure

The 48 great rhombicuboctahedral cells are joined to each other via their octagonal faces. They can be grouped into two groups of 24 each, corresponding with the cells of a 24-cell and its dual. The gaps between them are filled in by a network of 192 hexagonal prisms, joined to each other via alternating square faces in alternating orientation, and to the great rhombicuboctahedra via their hexagonal faces and remaining square faces.

Coordinates

The Cartesian coordinates of an omnitruncated 24-cell having edge length 2 are all permutations of coordinates and sign of:

(1, 1+√2, 1+2√2, 5+3√2)
(1, 3+√2, 3+2√2, 3+3√2)
(2, 2+√2, 2+2√2, 4+3√2)

Images

orthographic projections
Coxeter plane F4 B4
Graph
Dihedral symmetry [[12]] = [24] [8]
Coxeter plane B3 / A2 B2 / A3
Graph
Dihedral symmetry [6] [[4]] = [8]
3D perspective projections

Schlegel diagram

Perspective projection into 3D centered on a truncated cuboctahedron. The nearest great rhombicuboctahedral cell to the 4D viewpoint is shown in red, with the six surrounding great rhombicuboctahedra in yellow. Twelve of the hexagonal prisms sharing a square face with the nearest cell and hexagonal faces with the yellow cells are shown in blue. The remaining cells are shown in green. Cells lying on the far side of the polytope from the 4D viewpoint have been culled for clarity.
Net

Omnitruncated 24-cell

Dual to omnitruncated 24-cell

Full snub 24-cell

Vertex figure for omnisnub 24-cell

The uniform snub 24-cell is called a semi-snub 24-cell by John Horton Conway with Coxeter diagram within the F4 family, although it is a full snub or omnisnub within the D4 family, as .

In contrast a full snub 24-cell or omnisnub 24-cell, defined as an alternation of the omnitruncated 24-cell, can not be made uniform, but it can be given Coxeter diagram , and symmetry [[3,4,3]]+, order 1152, and constructed from 48 snub cubes, 192 octahedrons, and 576 tetrahedrons filling the gaps at the deleted vertices. Its vertex figure contains 4 tetrahedra, 2 octahedra, and 2 snub cubes. It has 816 cells, 2832 faces, 2592 edges, and 576 vertices.[2]

Related polytopes

Notes

  1. Richard Klitzing, 4D, s3s4o3x
  2. Richard Klitzing, 4D, s3s4s3s

References

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