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Truncated tetrahedron

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Truncated tetrahedron

(Click here for rotating model)
Type Archimedean solid
Uniform polyhedron
Elements F = 8, E = 18, V = 12 (χ = 2)
Faces by sides 4{3}+4{6}
Conway notation tT
Schläfli symbols t{3,3} = h2{4,3}
t0,1{3,3}
Wythoff symbol 2 3 | 3
Coxeter diagram =
Symmetry group Td, A3, [3,3], (*332), order 24
Rotation group T, [3,3]+, (332), order 12
Dihedral angle 3-6: 109°28′16″
6-6: 70°31′44″
References U02, C16, W6
Properties Semiregular convex

Colored faces

3.6.6
(Vertex figure)

Triakis tetrahedron
(dual polyhedron)

Net

In geometry, the truncated tetrahedron is an Archimedean solid. It has 4 regular hexagonal faces, 4 equilateral triangle faces, 12 vertices and 18 edges (of two types). It can be constructed by truncating all 4 vertices of a regular tetrahedron at one third of the original edge length.

A deeper truncation, removing a tetrahedron of half the original edge length from each vertex, is called rectification. The rectification of a tetrahedron produces an octahedron.[1]

A truncated tetrahedron is the Goldberg polyhedron GIII(1,1), containing triangular and hexagonal faces.

A truncated tetrahedron can be called a cantic cube, with Coxeter diagram, , having half of the vertices of the cantellated cube (rhombicuboctahedron), . There are two dual positions of this construction, and combining them creates the uniform compound of two truncated tetrahedra.

Area and volume

The area A and the volume V of a truncated tetrahedron of edge length a are:

Densest Packing

The densest packing of the Archimedean truncated tetrahedron is believed to be Φ = 207/208, as reported by two independent groups using Monte Carlo methods.[2][3] Although no mathematical proof exists that this is the best possible packing for the truncated tetrahedron, the high proximity to the unity and independency of the findings make it unlikely that an even denser packing is to be found. In fact, if the truncation of the corners is slightly smaller than that of an Archimedean truncated tetrahedron, this new shape can be used to completely fill space.[2]

Cartesian coordinates

Cartesian coordinates for the 12 vertices of a truncated tetrahedron centered at the origin, with edge length √8, are all permutations of (±1,±1,±3) with an even number of minus signs:

  • (+3,+1,+1), (+1,+3,+1), (+1,+1,+3)
  • (−3,−1,+1), (−1,−3,+1), (−1,−1,+3)
  • (−3,+1,−1), (−1,+3,−1), (−1,+1,−3)
  • (+3,−1,−1), (+1,−3,−1), (+1,−1,−3)
Orthogonal projection showing Cartesian coordinates inside it bounding box: (±3,±3,±3). The hexagonal faces of the truncated tetrahedra can be divided into 6 coplanar equilateral triangles. The 4 new vertices have Cartesian coordinates:
(-1,-1,-1), (-1,+1,+1),
(+1,-1,+1), (+1,+1,-1).
The set of vertex permutations (±1,±1,±3) with an odd number of minus signs forms a complementary truncated tetrahedron, and combined they form a uniform compound polyhedron.

Another simple construction exists in 4-space as cells of the truncated 16-cell, with vertices as coordinate permutation of:

(0,0,1,2)

Orthogonal projection

Orthogonal projection
Centered by Edge normal Face normal Edge Face/vertex
Image
Dual image
Projective
symmetry
[1] [1] [3] [4]

Spherical tiling

The truncated tetrahedron can also be represented as a spherical tiling, and projected onto the plane via a stereographic projection. This projection is conformal, preserving angles but not areas or lengths. Straight lines on the sphere are projected as circular arcs on the plane.


triangle-centered

hexagon-centered
Orthographic projection Stereographic projections

Friauf polyhedron

A lower symmetry version of the truncated tetrahedron (a truncated tetragonal disphenoid with order 8 D2d symmetry) is called a Friauf polyhedron in crystals such as complex metallic alloys. This form fits 5 Friauf polyhedra around an axis, giving a 72 degree dihedral angle on a subset of 6-6 edges.[4] Its named after J. B. Friauf and his 1927 paper The crystal structure of the intermetallic compound MgCu2. [5]

Use in architecture

Giant truncated tetrahedra were used for the "Man the Explorer" and "Man the Producer" theme pavilions in Expo 67. They were made of massive girders of steel bolted together in a geometric lattice. The truncated tetrahedra were interconnected with lattice steel platforms. All of these buildings were demolished after the end of Expo 67, as they had not been built to withstand the severity of the Montreal weather over the years. Their only remnants are in the Montreal city archives, the Public Archives Of Canada and the photo collections of tourists of the times.[6]


Truncated tetrahedral graph

Truncated tetrahedral graph
3-fold symmetry
Vertices12[7]
Edges18
Radius3
Diameter3[7]
Girth3[7]
Automorphisms24 (S4)[7]
Chromatic number3[7]
Chromatic index3[7]
PropertiesHamiltonian, regular, 3-vertex-connected, planar graph
Table of graphs and parameters

In the mathematical field of graph theory, a truncated tetrahedral graph is a Archimedean graph, the graph of vertices and edges of the truncated tetrahedron, one of the Archimedean solids. It has 12 vertices and 18 edges.[8] It is a connected cubic graph,[9] and connected cubic transitive graph.[10]

Circular Orthographic projections

4-fold symmetry

3-fold symmetry
Family of uniform tetrahedral polyhedra
Symmetry: [3,3], (*332) [3,3]+, (332)
{3,3} t{3,3} r{3,3} t{3,3} {3,3} rr{3,3} tr{3,3} sr{3,3}
Duals to uniform polyhedra
V3.3.3 V3.6.6 V3.3.3.3 V3.6.6 V3.3.3 V3.4.3.4 V4.6.6 V3.3.3.3.3

It is also a part of a sequence of cantic polyhedra and tilings with vertex configuration 3.6.n.6. In this wythoff construction the edges between the hexagons represent degenerate digons. Template:Cantic small table

Symmetry mutations

This polyhedron is topologically related as a part of sequence of uniform truncated polyhedra with vertex configurations (3.2n.2n), and [n,3] Coxeter group symmetry.

*n32 symmetry mutation of truncated spherical tilings: t{n,3}
Symmetry
*n32
[n,3]
Spherical Euclid. Compact hyperb. Paraco.
*232
[2,3]
*332
[3,3]
*432
[4,3]
*532
[5,3]
*632
[6,3]
*732
[7,3]
*832
[8,3]...
*∞32
[∞,3]
Truncated
figures
Symbol t{2,3} t{3,3} t{4,3} t{5,3} t{6,3} t{7,3} t{8,3} t{∞,3}
Triakis
figures
Config. V3.4.4 V3.6.6 V3.8.8 V3.10.10 V3.12.12 V3.14.14 V3.16.16 V3.∞.∞

See also

References

  1. ^ Chisholm, Matt; Avnet, Jeremy (1997). "Truncated Trickery: Truncatering". theory.org. Retrieved 2013-09-02.
  2. ^ a b "Crystalline Assemblies and Densest Packings of a Family of Truncated Tetrahedra and the Role of Directional Entropic Forces" (PDF). Dec 2011.
  3. ^ "A Packing of Truncated Tetrahedra that Nearly Fills All of Space" (PDF). Sep 2011.
  4. ^ http://met.iisc.ernet.in/~lord/webfiles/clusters/polyclusters.pdf
  5. ^ Friauf, J. B. The crystal structure of the intermetallic compound MgCu2 (1927) J. Am. Chem. Soc. 19, 3107-3114.
  6. ^ http://expo67.ncf.ca/man_the_producer_p1.html
  7. ^ a b c d e f An Atlas of Graphs, page=172, C105
  8. ^ An Atlas of Graphs, page=267, truncated tetrahedral graph
  9. ^ An Atlas of Graphs, page=130, connected cubic graphs, 12 vertices, C105
  10. ^ An Atlas of Graphs, page=161, connected cubic transitive graphs, 12 vertices, Ct11
  • Williams, Robert (1979). The Geometrical Foundation of Natural Structure: A Source Book of Design. Dover Publications, Inc. ISBN 0-486-23729-X. (Section 3-9)
  • Read, R. C.; Wilson, R. J. (1998), An Atlas of Graphs, Oxford University Press