QUATERNION GROUP

In group theory, the 'quaternion group' is a non-abelian group of order 8. It is often denoted by ''Q'' and written in multiplicative form, with the following 8 elements
:''Q'' = {1, −1, ''i'', −''i'', ''j'', −''j'', ''k'', −''k''}
Here 1 is the identity element, (−1)² = 1, and (−1)''a'' = ''a''(−1) = −''a'' for all ''a'' in ''Q''. The remaining multiplication rules can be obtained from the following relation:
:$i^2\; =\; j^2\; =\; k^2\; =\; ijk\; =\; -1$
The entire Cayley table (multiplication table) for ''Q'' is given by:

	1	i	j	k	−1	−i	−j	−k
1	1	i	j	k	−1	−i	−j	−k
i	i	−1	k	−j	−i	1	−k	j
j	j	−k	−1	i	−j	k	1	−i
k	k	j	−i	−1	−k	−j	i	1
−1	−1	−i	−j	−k	1	i	j	k
−i	−i	1	−k	j	i	−1	k	−j
−j	−j	k	1	−i	j	−k	−1	i
−k	−k	−j	i	1	k	j	−i	−1

Note that the resulting group is non-commutative; for example ''ij'' = −''ji''. ''Q'' has the unusual property of being Hamiltonian: every subgroup of ''Q'' is a normal subgroup, but the group is non-abelian. Every Hamiltonian group contains a copy of ''Q''.
In abstract algebra, one can construct a real 4-dimensional vector space with basis {1, ''i'', ''j'', ''k''} and turn it into an associative algebra by using the above multiplication table and distributivity. The result is a skew field called the '''quaternions'''. Note that this is not quite the group algebra on ''Q'' (which would be 8-dimensional). Conversely, one can start with the quaternions and ''define'' the quaternion group as the multiplicative subgroup consisting of the eight elements {1, −1, ''i'', −''i'', ''j'', −''j'', ''k'', −''k''}.
Note that ''i'', ''j'', and ''k'' all have order 4 in ''Q'' and any two of them generate the entire group. ''Q'' has the presentation
:$langle\; x,y\; mid\; x^4\; =\; 1,\; x^2\; =\; y^2,\; yxy^\{-1\}\; =\; x^\{-1\}$
angle
One may take, for instance, ''i'' = ''x'', ''j'' = ''y'' and ''k'' = ''xy''.
The center and the commutator subgroup of ''Q'' is the subgroup {±1}. The factor group ''Q''/{±1} is isomorphic to the Klein four-group ''V''. The inner automorphism group of ''Q'' is isomorphic to ''Q'' modulo its center, and is therefore also isomorphic to the Klein four-group. The full automorphism group of ''Q'' is isomorphic to ''S''₄, the symmetric group on four letters. The outer automorphism group of ''Q'' is then ''S''₄/''V'' which is isomorphic to ''S''₃.
The quaternion group ''Q'' may be regarded as acting on the eight nonzero elements of the 2-dimensional vector space over the finite field 'GF'(3).

Contents

Matrix representation of the quaternion group

Generalized quaternion group

References

See also

Matrix representation of the quaternion group

The quaternion group can be represented as a subgroup of the general linear group GL₂('C').
Q={
pm 1
end{align},
pm i
end{align},
pm j
end{align},
pm k
end{align}}
such that

1 & 0 \
0 & 1
end{Bmatrix}

i & 0 \
0 & -i
end{Bmatrix}

0 & 1 \
-1 & 0
end{Bmatrix}

0 & i \
i & 0
end{Bmatrix}
'note:' the $i$s inside the matrices represent the imaginary number $i$.
The same identities already established in this article can be affirmed using the existing laws of composition for GL₂('C').^[1]

Generalized quaternion group

A group is called a 'generalized quaternion group' if it has a presentation
:$langle\; x,y\; mid\; x^\{2^\{n-1\}\}\; =\; 1,\; x^\{2^\{n-2\}\}\; =\; y^2,\; yxy^\{-1\}\; =\; x^\{-1\}$
angle
for some integer ''n'' ≥ 3. The order of this group is 2^''n''. The ordinary quaternion group corresponds to the case ''n'' = 3. The generalized quaternion group can be realized as the subgroup of unit quaternions generated by
:$x\; =\; e^\{2pi\; i/2^\{n-1\}\}$
:$y\; =\; j,$
The generalized quaternion groups are members of the still larger family of dicyclic groups. The generalized quaternion groups have the property that every abelian subgroup is cyclic. It can be shown that a finite p-group with this property (every abelian subgroup is cyclic) is either cyclic or a generalized quaternion group as defined above.
Another characterization is that a finite p-group in which there is a unique subgroup of order p is either cyclic or generalized quaternion.
In particular, for a finite field F with odd characteristic, the 2-Sylow subgroup of SL₂(F) is non-abelian and has only one subgroup
of order 2, so this 2-Sylow subgroup must be a generalized quaternion group. Letting q = p^r be the size of F, where ''p'' is prime,
the size of the 2-Sylow subgroup of SL₂(F) is 2^''n'', where ''n'' = ord₂(''p''² - 1) + ord₂(''r'').

References

1. Algebra, Michael Artin, , , Prentice Hall, 1991,

See also

★ Quaternion

★ Klein four-group

★ dicyclic group

★ binary tetrahedral group

★ Hurwitz integral quaternion

★ 16-cell