In mathematics, and especially in geometry, an object has icosahedral symmetry if it has the same symmetries as a regular icosahedron. Examples of other polyhedra with icosahedral symmetry include the regular dodecahedron (the dual of the icosahedron) and the rhombic triacontahedron.
Every polyhedron with icosahedral symmetry has 60 rotational (or orientation-preserving) symmetries and 60 orientation-reversing symmetries (that combine a rotation and a reflection), for a total symmetry order of 120. The full symmetry group is the Coxeter group of type . It may be represented by Coxeter notation and Coxeter diagram . The set of rotational symmetries forms a subgroup that is isomorphic to the alternating group on 5 letters.
Apart from the two infinite series of prismatic and antiprismatic symmetry, rotational icosahedral symmetry or chiral icosahedral symmetry of chiral objects and full icosahedral symmetry or achiral icosahedral symmetry are the discrete point symmetries (or equivalently, symmetries on the sphere) with the largest symmetry groups.
Icosahedral symmetry is not compatible with translational symmetry, so there are no associated crystallographic point groups or space groups.
Presentations corresponding to the above are:
These correspond to the icosahedral groups (rotational and full) being the (2,3,5) triangle groups.
The first presentation was given by William Rowan Hamilton in 1856, in his paper on icosian calculus.
Note that other presentations are possible, for instance as an alternating group (for I).
The full symmetry group is the Coxeter group of type . It may be represented by Coxeter notation and Coxeter diagram . The set of rotational symmetries forms a subgroup that is isomorphic to the alternating group on 5 letters.
Every polyhedron with icosahedral symmetry has 60 rotational (or orientation-preserving) symmetries and 60 orientation-reversing symmetries (that combine a rotation and a reflection), for a total symmetry order of 120.
The I is of order 60. The group I is isomorphic to A<sub>5</sub>, the alternating group of even permutations of five objects. This isomorphism can be realized by I acting on various compounds, notably the compound of five cubes (which inscribe in the dodecahedron), the compound of five octahedra, or either of the two compounds of five tetrahedra (which are enantiomorphs, and inscribe in the dodecahedron). The group contains 5 versions of T<sub>h</sub> with 20 versions of D<sub>3</sub> (10 axes, 2 per axis), and 6 versions of D<sub>5</sub>.
The I<sub>h</sub> has order 120. It has I as normal subgroup of index 2. The group I<sub>h</sub> is isomorphic to I ÃÂ Z<sub>2</sub>, or A<sub>5</sub> ÃÂ Z<sub>2</sub>, with the inversion in the center corresponding to element (identity,-1), where Z<sub>2</sub> is written multiplicatively.
I<sub>h</sub> acts on the compound of five cubes and the compound of five octahedra, but âÂÂ1 acts as the identity (as cubes and octahedra are centrally symmetric). It acts on the compound of ten tetrahedra: I acts on the two chiral halves (compounds of five tetrahedra), and âÂÂ1 interchanges the two halves. Notably, it does not act as S<sub>5</sub>, and these groups are not isomorphic; see below for details.
The group contains 10 versions of D<sub>3d</sub> and 6 versions of D<sub>5d</sub> (symmetries like antiprisms).
I is also isomorphic to PSL<sub>2</sub>(5), but I<sub>h</sub> is not isomorphic to SL<sub>2</sub>(5).
It is useful to describe explicitly what the isomorphism between I and A<sub>5</sub> looks like. In the following table, permutations P<sub>i</sub> and Q<sub>i</sub> act on 5 and 12 elements respectively, while the rotation matrices M<sub>i</sub> are the elements of I. If P<sub>k</sub> is the product of taking the permutation P<sub>i</sub> and applying P<sub>j</sub> to it, then for the same values of i, j and k, it is also true that Q<sub>k</sub> is the product of taking Q<sub>i</sub> and applying Q<sub>j</sub>, and also that premultiplying a vector by M<sub>k</sub> is the same as premultiplying that vector by M<sub>i</sub> and then premultiplying that result with M<sub>j</sub>, that is M<sub>k</sub> = M<sub>j</sub> ÃÂ M<sub>i</sub>. Since the permutations P<sub>i</sub> are all the 60 even permutations of 12345, the one-to-one correspondence is made explicit, therefore the isomorphism too.
This non-abelian simple group is the only non-trivial normal subgroup of the symmetric group on five letters. Since the Galois group of the general quintic equation is isomorphic to the symmetric group on five letters, and this normal subgroup is simple and non-abelian, the general quintic equation does not have a solution in radicals. The proof of the AbelâÂÂRuffini theorem uses this simple fact, and Felix Klein wrote a book that made use of the theory of icosahedral symmetries to derive an analytical solution to the general quintic equation. A modern exposition is given in .
The following groups all have order 120, but are not isomorphic:
They correspond to the following short exact sequences (the latter of which does not split) and product
In words,
Note that has an exceptional irreducible 3-dimensional representation (as the icosahedral rotation group), but does not have an irreducible 3-dimensional representation, corresponding to the full icosahedral group not being the symmetric group.
These can also be related to linear groups over the finite field with five elements, which exhibit the subgroups and covering groups directly; none of these are the full icosahedral group:
The 120 symmetries fall into 10 conjugacy classes.
Each line in the following table represents one class of conjugate (i.e., geometrically equivalent) subgroups. The column "Mult." (multiplicity) gives the number of different subgroups in the conjugacy class.
Explanation of colors: green = the groups that are generated by reflections, red = the chiral (orientation-preserving) groups, which contain only rotations.
The groups are described geometrically in terms of the dodecahedron.
The abbreviation "h.t.s.(edge)" means "halfturn swapping this edge with its opposite edge", and similarly for "face" and "vertex".
Stabilizers of an opposite pair of vertices can be interpreted as stabilizers of the axis they generate.
Stabilizers of an opposite pair of edges can be interpreted as stabilizers of the rectangle they generate.
Stabilizers of an opposite pair of faces can be interpreted as stabilizers of the antiprism they generate.
For each of these, there are 5 conjugate copies, and the conjugation action gives a map, indeed an isomorphism, .
The full icosahedral symmetry group [5,3] () of order 120 has generators represented by the reflection matrices R<sub>0</sub>, R<sub>1</sub>, R<sub>2</sub> below, with relations R<sub>0</sub><sup>2</sup> = R<sub>1</sub><sup>2</sup> = R<sub>2</sub><sup>2</sup> = (R<sub>0</sub>ÃÂR<sub>1</sub>)<sup>5</sup> = (R<sub>1</sub>ÃÂR<sub>2</sub>)<sup>3</sup> = (R<sub>0</sub>ÃÂR<sub>2</sub>)<sup>2</sup> = Identity. The group [5,3]<sup>+</sup> () of order 60 is generated by any two of the rotations S<sub>0,1</sub>, S<sub>1,2</sub>, S<sub>0,2</sub>. A rotoreflection of order 10 is generated by V<sub>0,1,2</sub>, the product of all 3 reflections. Here denotes the golden ratio.
Fundamental domains for the icosahedral rotation group and the full icosahedral group are given by:
In the disdyakis triacontahedron one full face is a fundamental domain; other solids with the same symmetry can be obtained by adjusting the orientation of the faces, e.g. flattening selected subsets of faces to combine each subset into one face, or replacing each face by multiple faces, or a curved surface.
Examples of other polyhedra with icosahedral symmetry include the regular dodecahedron (the dual of the icosahedron) and the rhombic triacontahedron.
For the intermediate material phase called liquid crystals the existence of icosahedral symmetry was proposed by H. Kleinert and K. Maki and its structure was first analyzed in detail in that paper. See the review article here. In aluminum, the icosahedral structure was discovered experimentally three years after this by Dan Shechtman, which earned him the Nobel Prize in 2011.
At small sizes, many elements form icosahedral nanoparticles, which are often lower in energy than single crystals.
Icosahedral symmetry is equivalently the projective special linear group PSL(2,5), and is the symmetry group of the modular curve X(5), and more generally PSL(2,p) is the symmetry group of the modular curve X(p). The modular curve X(5) is geometrically a dodecahedron with a cusp at the center of each polygonal face, which demonstrates the symmetry group.
This geometry, and associated symmetry group, was studied by Felix Klein as the monodromy groups of a Belyi surface â a Riemann surface with a holomorphic map to the Riemann sphere, ramified only at 0, 1, and infinity (a Belyi function) â the cusps are the points lying over infinity, while the vertices and the centers of each edge lie over 0 and 1; the degree of the covering (number of sheets) equals 5.
Klein's investigations continued with his discovery of order 7 and order 11 symmetries in and (and associated coverings of degree 7 and 11) and dessins d'enfants, the first yielding the Klein quartic, whose associated geometry has a tiling by 24 heptagons (with a cusp at the center of each).
Similar geometries occur for PSL(2,n) and more general groups for other modular curves.
More exotically, there are special connections between the groups PSL(2,5) (order 60), PSL(2,7) (order 168) and PSL(2,11) (order 660), which also admit geometric interpretations â PSL(2,5) is the symmetries of the icosahedron (genus 0), PSL(2,7) of the Klein quartic (genus 3), and PSL(2,11) the buckyball surface (genus 70). These groups form a "trinity" in the sense of Vladimir Arnold, which gives a framework for the various relationships; see trinities for details.
There is a close relationship to other Platonic solids.
Poincare used the rotational symmetry group to construct the Poincare homology sphere as the quotient manifold , an important example of a space whose homology is the same as that of the sphere , but which is not homotopic to it.