icosahedral group

In my geometry 101 course I'm doing the rotation-symmetry groups
of the Platonic solids right now. This goes slightly slower than
expected as it turned out that some secondary schools no longer give a
formal definition of what a group is. So, a lot of time is taken up
explaining permutations and their properties as I want to view the
Platonic groups as subgroups of the permutation groups on the vertices.
To prove that the _tetrahedral group_ is isomorphic to $A_{4}$ was pretty
straigthforward and I'm half way through proving that the
_octahedral group_ is just $S_{4}$ (using the duality of the octahedron
with the cube and using the $4$ body diagonals of the cube).
Next
week I have to show that the _icosahedral group_ is isomorphic to $A_{5}$
which is a lot harder. The usual proof (that is, using the duality
between the icosahedron and the dodecahedron and using the $5$ cubes
contained in the dodecahedron, one for each of the diagonals of a face)
involves too much calculations to do in one hour. An alternative road is
to view the icosahedral group as a subgroup of $S_{6}$ (using the main
diagonals on the $12$ vertices of the icosahedron) and identifying this
subgroup as $A_{5}$ . A neat exposition of this approach is given by John Baez in his
post Some thoughts on
the number $6$ . (He also has another post on the icosahedral group
in his Week 79's
finds in mathematical physics).

But
probably I'll go for an “In Gap we
thrust”-argument. Using the numbers on the left, the rotation by
$72^{o}$ counter-clockwise in the top face we get the permutation in
$S_{20}$
$(1, 2, 3, 4, 5) (6, 8, 10, 12, 14) (7, 9, 11, 13, 15) (16, 17, 18, 19, 20)$
and the
rotation by $72^{o}$ counterclockwise along the face $(1, 2, 8, 7, 8)$ gives
the permutation
$(1, 6, 7, 8, 2) (3, 5, 15, 16, 9) (4, 14, 20, 17, 10) (12, 13, 19, 18, 11)$
GAP
calculates that the subgroup $d o d e$ of $S_{20}$ generated by these two
elements is $60$ (the correct number) and with $I s S i m p l e g r o u p (d o d e);$ we
find that this group must be simple. Finally using
$I s o m o r p h i s m T y p e I n f o F i n i t e S i m p l e g r o u p (d o d e);$
we get the required
result that the group is indeed isomorphic to $A_{5}$ . The time saved I
can then use to tell something about the classification project of
finite simple groups which might be more inspiring than tedious
calculations…

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