Snub dodecahedron

Snub dodecahedral graph
Snub dodecahedral graph
	5-fold symmetry Schlegel diagram
Vertices	60
Edges	150
Automorphisms	60
Properties	Hamiltonian, regular
	Table of graphs and parameters

Snub dodecahedron
(Click here for rotating model)
Type	Archimedean solid Uniform polyhedron
Elements	F = 92, E = 150, V = 60 (χ = 2)
Faces by sides	(20+60){3}+12{5}
Conway notation	sD
Schläfli symbols	sr{5,3} or $s{\begin{Bmatrix}5\\3\end{Bmatrix}}$
Schläfli symbols	ht_0,1,2{5,3}
Wythoff symbol	\| 2 3 5
Coxeter diagram
Symmetry group	I, 1/2H₃, [5,3]⁺, (532), order 60
Rotation group	I, [5,3]⁺, (532), order 60
Dihedral angle	3-3: 164°10′31″ (164.18°) 3-5: 152°55′53″ (152.93°)
References	U₂₉, C₃₂, W₁₈
Properties	Semiregular convex chiral
Colored faces	3.3.3.3.5 (Vertex figure)
Pentagonal hexecontahedron (dual polyhedron)	Net

In geometry, the snub dodecahedron, or snub icosidodecahedron, is an Archimedean solid, one of thirteen convex isogonal nonprismatic solids constructed by two or more types of regular polygon faces.

The snub dodecahedron has 92 faces (the most of the 13 Archimedean solids): 12 are pentagons and the other 80 are equilateral triangles. It also has 150 edges, and 60 vertices.

It has two distinct forms, which are mirror images (or "enantiomorphs") of each other. The union of both forms is a compound of two snub dodecahedra, and the convex hull of both forms is a truncated icosidodecahedron.

Kepler first named it in Latin as dodecahedron simum in 1619 in his Harmonices Mundi. H. S. M. Coxeter, noting it could be derived equally from either the dodecahedron or the icosahedron, called it snub icosidodecahedron, with a vertical extended Schläfli symbol $s\scriptstyle {\begin{Bmatrix}5\\3\end{Bmatrix}}$ and flat Schläfli symbol $sr{5,3}.$

Cartesian coordinates[edit]

Let $ξ \approx 0.943 15125924$ be the real zero of the cubic polynomial $x 3 + 2 x 2 - φ 2$ , where $φ$ is the golden ratio. Let the point $p$ be given by

p={\begin{pmatrix}\varphi ^{2}-\varphi ^{2}\xi \\-\varphi ^{3}+\varphi \xi +2\varphi \xi ^{2}\\\xi \end{pmatrix}}.

Let the rotation matrices

M 1

and

M 2

be given by

M_{1}={\begin{pmatrix}{\frac {1}{2\varphi }}&-{\frac {\varphi }{2}}&{\frac {1}{2}}\\{\frac {\varphi }{2}}&{\frac {1}{2}}&{\frac {1}{2\varphi }}\\-{\frac {1}{2}}&{\frac {1}{2\varphi }}&{\frac {\varphi }{2}}\end{pmatrix}},\quad M_{2}={\begin{pmatrix}0&0&1\\1&0&0\\0&1&0\end{pmatrix}}.

M 1

represents the rotation around the axis

(0, 1, φ)

through an angle of 2

π

5 counterclockwise, while

M 2

being a cyclic shift of

(x, y, z)

represents the rotation around the axis

(1, 1, 1)

through an angle of 2

π

3. Then the 60 vertices of the snub dodecahedron are the 60 images of point

p

under repeated multiplication by

M 1

and/or

M 2

, iterated to convergence. (The matrices

M 1

and

M 2

generate the 60 rotation matrices corresponding to the 60 rotational symmetries of a regular icosahedron.) The coordinates of the vertices are integral linear combinations of

1, φ, ξ, φξ, ξ 2

and

φξ 2

. The edge length equals

2\xi {\sqrt {1-\xi }}\approx 0.449\,750\,618\,41.

Negating all coordinates gives the mirror image of this snub dodecahedron.

As a volume, the snub dodecahedron consists of 80 triangular and 12 pentagonal pyramids. The volume $V 3$ of one triangular pyramid is given by:

V_{3}={\frac {1}{3}}\varphi \left(3\xi ^{2}-\varphi ^{2}\right)\approx 0.027\,274\,068\,85,

and the volume

V 5

of one pentagonal pyramid by:

V_{5}={\frac {1}{3}}(3\varphi +1)\left(\varphi +3-2\xi -3\xi ^{2}\right)\xi ^{3}\approx 0.103\,349\,665\,04.

The total volume is

80V_{3}+12V_{5}\approx 3.422\,121\,488\,76.

The circumradius equals

{\sqrt {4\xi ^{2}-\varphi ^{2}}}\approx 0.969\,589\,192\,65.

The midradius equals

ξ

. This gives an interesting geometrical interpretation of the number

ξ

. The 20 "icosahedral" triangles of the snub dodecahedron described above are coplanar with the faces of a regular icosahedron. The midradius of this "circumscribed" icosahedron equals 1. This means that

ξ

is the ratio between the midradii of a snub dodecahedron and the icosahedron in which it is inscribed.

The triangle–triangle dihedral angle is given by

\theta _{33}=180^{\circ }-\arccos \left({\frac {2}{3}}\xi +{\frac {1}{3}}\right)\approx 164.175\,366\,056\,03^{\circ }.

The triangle–pentagon dihedral angle is given by

{\begin{aligned}\theta _{35}&=180^{\circ }-\arccos {\sqrt {\frac {-(4\varphi +8)\xi ^{2}-(4\varphi +8)\xi +12\varphi +19}{15}}}\\[2pt]&\approx 152.929\,920\,275\,84^{\circ }.\end{aligned}}

Metric properties[edit]

For a snub dodecahedron whose edge length is 1, the surface area is

A=20{\sqrt {3}}+3{\sqrt {25+10{\sqrt {5}}}}\approx 55.286\,744\,958\,445\,15.

Its volume is

V={\frac {(3\varphi +1)\xi ^{2}+(3\varphi +1)\xi -\varphi /6-2}{\sqrt {3\xi ^{2}-\varphi ^{2}}}}\approx 37.616\,649\,962\,733\,36.

Alternatively, this volume may be written as

{\begin{aligned}V&={\frac {5+5{\sqrt {5}}}{6{\sqrt {3}}}}{\sqrt {{18+6{\sqrt {5}}}+{a\left({3+3{\sqrt {5}}}+a\right)}}}+{\frac {5+3{\sqrt {5}}}{24{\sqrt {2}}}}{\sqrt {72+{\left({5+{\sqrt {5}}}\right)}a\left({3+3{\sqrt {5}}}+a\right)}}\\[2pt]&\approx 37.616\,649\,962\,733\,36,\end{aligned}}

where

{\begin{aligned}a&={\sqrt[{3}]{54(1+{\sqrt {5}})+6{\sqrt {102+162{\sqrt {5}}}}}}+{\sqrt[{3}]{54(1+{\sqrt {5}})-6{\sqrt {102+162{\sqrt {5}}}}}}\\[2pt]&\approx 10.293\,368\,998\,184\,21.\end{aligned}}

Its circumradius is

R={\frac {1}{2}}{\sqrt {\frac {2-\xi }{1-\xi }}}\approx 2.155\,837\,375.

Its midradius is

r={\frac {1}{2}}{\sqrt {\frac {1}{1-\xi }}}\approx 2.097\,053\,835\,25.

There are two inscribed spheres, one touching the triangular faces, and one, slightly smaller, touching the pentagonal faces. Their radii are, respectively:

{\begin{aligned}r_{3}&={\frac {\varphi {\sqrt {3}}}{6\xi }}{\sqrt {\frac {1}{1-\xi }}}\approx 2.077\,089\,659\,74\\[4pt]r_{5}&={\frac {1}{2}}{\sqrt {\varphi ^{2}\xi ^{2}+3\varphi ^{2}\xi +{\frac {11}{5}}\varphi +{\frac {12}{5}}}}\approx 1.980\,915\,947\,28.\end{aligned}}

The four positive real roots of the sextic equation in R²

4096R^{12}-27648R^{10}+47104R^{8}-35776R^{6}+13872R^{4}-2696R^{2}+209=0

are the circumradii of the snub dodecahedron (U₂₉), great snub icosidodecahedron (U₅₇), great inverted snub icosidodecahedron (U₆₉), and great retrosnub icosidodecahedron (U₇₄).

The snub dodecahedron has the highest sphericity of all Archimedean solids. If sphericity is defined as the ratio of volume squared over surface area cubed, multiplied by a constant of 36 $π$ (where this constant makes the sphericity of a sphere equal to 1), the sphericity of the snub dodecahedron is about 0.947.^[1]

Orthogonal projections[edit]

The snub dodecahedron has two especially symmetric orthogonal projections as shown below, centered on two types of faces: triangles and pentagons, corresponding to the A₂ and H₂ Coxeter planes.

Orthogonal projections
Centered by	Face Triangle	Face Pentagon	Edge
Solid
Wireframe
Projective symmetry	[3]	[5]⁺	[2]
Dual

Geometric relations[edit]

Dodecahedron, rhombicosidodecahedron and snub dodecahedron (animated expansion and twisting)

Uniform alternation of a truncated icosidodecahedron

The snub dodecahedron can be generated by taking the twelve pentagonal faces of the dodecahedron and pulling them outward so they no longer touch. At a proper distance this can create the rhombicosidodecahedron by filling in square faces between the divided edges and triangle faces between the divided vertices. But for the snub form, pull the pentagonal faces out slightly less, only add the triangle faces and leave the other gaps empty (the other gaps are rectangles at this point). Then apply an equal rotation to the centers of the pentagons and triangles, continuing the rotation until the gaps can be filled by two equilateral triangles. (The fact that the proper amount to pull the faces out is less in the case of the snub dodecahedron can be seen in either of two ways: the circumradius of the snub dodecahedron is smaller than that of the icosidodecahedron; or, the edge length of the equilateral triangles formed by the divided vertices increases when the pentagonal faces are rotated.)

The snub dodecahedron can also be derived from the truncated icosidodecahedron by the process of alternation. Sixty of the vertices of the truncated icosidodecahedron form a polyhedron topologically equivalent to one snub dodecahedron; the remaining sixty form its mirror-image. The resulting polyhedron is vertex-transitive but not uniform.

Alternatively, combining the vertices of the snub dodecahedron given by the Cartesian coordinates (above) and its mirror will form a semiregular truncated icosidodecahedron. The comparisons between these regular and semiregular polyhedrons is shown in the figure to the right.

Cartesian coordinates for the vertices of this alternative snub dodecahedron are obtained by selecting sets of 12 (of 24 possible even permutations contained in the five sets of truncated icosidodecahedron Cartesian coordinates). The alternations are those with an odd number of minus signs in these three sets:

Overlay of regular and semiregular truncated icosidodecahedra and snub dodecahedra

{\begin{array}{ccccccc}{\Bigl (}&\pm {\tfrac {1}{\varphi }}&,&\pm {\tfrac {1}{\varphi }}&,&\pm [3+\varphi ]&{\Bigr )},\\[2pt]{\Bigl (}&\pm {\tfrac {1}{\varphi }}&,&\pm \,\varphi ^{2}&,&\pm [3\varphi -1]&{\Bigr )},\\[2pt]{\Bigl (}&\pm [2\varphi -1]&,&\pm \,2&,&\pm [2+\varphi ]&{\Bigr )},\end{array}}

and an even number of minus signs in these two sets:

{\begin{array}{ccccccc}{\Bigl (}&\pm {\tfrac {2}{\varphi }}&,&\pm \,\varphi &,&\pm [1+2\varphi ]&{\Bigr )},\\[2pt]{\Bigl (}&\pm \,\varphi &,&\pm \,3&,&\pm \,2\varphi &{\Bigr )},\end{array}}

where $\varphi ={\tfrac {1+{\sqrt {5}}}{2}}$ is the golden ratio. The mirrors of both the regular truncated icosidodecahedron and this alternative snub dodecahedron are obtained by switching the even and odd references to both sign and position permutations.

Related polyhedra and tilings[edit]

Family of uniform icosahedral polyhedra
Symmetry: [5,3], (*532)							[5,3]⁺, (532)


{5,3}	t{5,3}	r{5,3}	t{3,5}	{3,5}	rr{5,3}	tr{5,3}	sr{5,3}
Duals to uniform polyhedra

V5.5.5	V3.10.10	V3.5.3.5	V5.6.6	V3.3.3.3.3	V3.4.5.4	V4.6.10	V3.3.3.3.5

This semiregular polyhedron is a member of a sequence of snubbed polyhedra and tilings with vertex figure (3.3.3.3.n) and Coxeter–Dynkin diagram . These figures and their duals have (n32) rotational symmetry, being in the Euclidean plane for n = 6, and hyperbolic plane for any higher n. The series can be considered to begin with n = 2, with one set of faces degenerated into digons.

n32 symmetry mutations of snub tilings: 3.3.3.3.n v t e
Symmetry n32	Spherical				Euclidean	Compact hyperbolic		Paracomp.
Symmetry n32	232	332	432	532	632	732	832	∞32
Snub figures
Config.	3.3.3.3.2	3.3.3.3.3	3.3.3.3.4	3.3.3.3.5	3.3.3.3.6	3.3.3.3.7	3.3.3.3.8	3.3.3.3.∞
Gyro figures
Config.	V3.3.3.3.2	V3.3.3.3.3	V3.3.3.3.4	V3.3.3.3.5	V3.3.3.3.6	V3.3.3.3.7	V3.3.3.3.8	V3.3.3.3.∞

Snub dodecahedral graph[edit]

In the mathematical field of graph theory, a snub dodecahedral graph is the graph of vertices and edges of the snub dodecahedron, one of the Archimedean solids. It has 60 vertices and 150 edges, and is an Archimedean graph.^[2]

References[edit]

^ Aravind, P. K. (March 2011), "How Spherical Are the Archimedean Solids and Their Duals?", The College Mathematics Journal, 42 (2): 98–107, doi:10.4169/college.math.j.42.2.098
^ Read, R. C.; Wilson, R. J. (1998), An Atlas of Graphs, Oxford University Press, p. 269

Jayatilake, Udaya (March 2005). "Calculations on face and vertex regular polyhedra". Mathematical Gazette. 89 (514): 76–81. doi:10.1017/S0025557200176818. S2CID 125675814.
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)
Cromwell, P. (1997). Polyhedra. United Kingdom: Cambridge. pp. 79–86 Archimedean solids. ISBN 0-521-55432-2.

External links[edit]

Weisstein, Eric W., "Snub dodecahedron" ("Archimedean solid") at MathWorld.
- Weisstein, Eric W. "Snub dodecahedral graph". MathWorld.
Klitzing, Richard. "3D convex uniform polyhedra s3s5s - snid".
Editable printable net of a Snub Dodecahedron with interactive 3D view
The Uniform Polyhedra
Virtual Reality Polyhedra The Encyclopedia of Polyhedra
Mark S. Adams and Menno T. Kosters. Volume Solutions to the Snub Dodecahedron

[1] Aravind, P. K. (March 2011), "How Spherical Are the Archimedean Solids and Their Duals?", The College Mathematics Journal, 42 (2): 98–107, doi:10.4169/college.math.j.42.2.098

[2] Read, R. C.; Wilson, R. J. (1998), An Atlas of Graphs, Oxford University Press, p. 269

[1]

[2]