Triangular bipyramid

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Short description: 12th Johnson solid; two tetrahedra joined along one face
Triangular bipyramid
Triangular dipyramid.png
TypeBipyramid,
Johnson
J11J12J13
Faces6 triangles
Edges9
Vertices5
Schläfli symbol{ } + {3}
Coxeter diagramCDel node f1.pngCDel 2x.pngCDel node f1.pngCDel 3.pngCDel node.png
Symmetry groupD3h, [3,2], (*223), order 12
Rotation groupD3, [3,2]+, (223), order 6
Dual polyhedronTriangular prism
Face configurationV3.4.4
PropertiesConvex, face-transitive

File:J12 triangular bipyramid.stl

Net

In geometry, the triangular bipyramid (or dipyramid) is a type of hexahedron, being the first in the infinite set of face-transitive bipyramids. It is the dual of the triangular prism with 6 isosceles triangle faces.

As the name suggests, it can be constructed by joining two tetrahedra along one face. Although all its faces are congruent and the solid is face-transitive, it is not a Platonic solid because some vertices adjoin three faces and others adjoin four.

The bipyramid whose six faces are all equilateral triangles is one of the Johnson solids, (J12). A Johnson solid is one of 92 strictly convex polyhedra that is composed of regular polygon faces but are not uniform polyhedra (that is, they are not Platonic solids, Archimedean solids, prisms, or antiprisms). They were named by Norman Johnson, who first listed these polyhedra in 1966.[1] As a Johnson solid with all faces equilateral triangles, it is also a deltahedron.

Formulae

The following formulae for the height ([math]\displaystyle{ H }[/math]), surface area ([math]\displaystyle{ A }[/math]) and volume ([math]\displaystyle{ V }[/math]) can be used if all faces are regular, with edge length [math]\displaystyle{ L }[/math]:[2]

[math]\displaystyle{ H = L\cdot \frac{2\sqrt{6}}{3} \approx L\cdot 1.632993162 }[/math]
[math]\displaystyle{ A = L^2 \cdot \frac{3\sqrt{3}}{2} \approx L^2\cdot 2.598076211 }[/math]
[math]\displaystyle{ V = L^3 \cdot \frac{\sqrt{2}}{6} \approx L^3\cdot 0.235702260 }[/math]

Dual polyhedron

The dual polyhedron of the triangular bipyramid is the triangular prism, with five faces: two parallel equilateral triangles linked by a chain of three rectangles. Although the triangular prism has a form that is a uniform polyhedron (with square faces), the dual of the Johnson solid form of the bipyramid has rectangular rather than square faces, and is not uniform.

Triangular prism Net
Dual triangular dipyramid.png Dual triangular dipyramid net.png

Related polyhedra and honeycombs

The triangular bipyramid, dt{2,3}, can be in sequence rectified, rdt{2,3}, truncated, trdt{2,3} and alternated (snubbed), srdt{2,3}:

Snub rectified triangular bipyramid sequence.png

The triangular bipyramid can be constructed by augmentation of smaller ones, specifically two stacked regular octahedra with 3 triangular bipyramids added around the sides, and 1 tetrahedron above and below. This polyhedron has 24 equilateral triangle faces, but it is not a Johnson solid because it has coplanar faces. It is a coplanar 24-triangle deltahedron. This polyhedron exists as the augmentation of cells in a gyrated alternated cubic honeycomb. Larger triangular polyhedra can be generated similarly, like 9, 16 or 25 triangles per larger triangle face, seen as a section of a triangular tiling.

Triangulated bipyramid.png

The triangular bipyramid can form a tessellation of space with octahedra or with truncated tetrahedra.[3]

Tetrahedral-truncated tetrahedral honeycomb slab.png
Layers of the uniform quarter cubic honeycomb can be shifted to pair up regular tetrahedral cells which combined into triangular bipyramids.
Tetroctahedric semicheck.png
The gyrated tetrahedral-octahedral honeycomb has pairs of adjacent regular tetrahedra that can be seen as triangular bipyramids.

When projected onto a sphere, it resembles a compound of a trigonal hosohedron and trigonal dihedron. It is part of an infinite series of dual pair compounds of regular polyhedra projected onto spheres. The triangular bipyramid can be referred to as a deltoidal hexahedron for consistency with the other solids in the series, although the "deltoids" are triangles instead of kites in this case, as the angle from the dihedron is 180 degrees.


See also


References

External links