MAXIMAL TORUS

In the mathematical theory of compact Lie groups a special role is played by torus subgroups, in a particular by the 'maximal torus' subgroups.
A 'torus' in a Lie group ''G'' is a compact, connected, abelian Lie subgroup of ''G'' (and therefore isomorphic to the standard torus 'T'^''n''). A 'maximal torus' is one which is maximal among such subgroups. That is, ''T'' is a maximal torus if for any other torus ''T''′ containing ''T'' we have ''T'' = ''T''′. Every torus is contained in a maximal torus simply by dimensional considerations. A noncompact Lie group need not have any nontrivial tori (e.g. 'R'^''n'').
The dimension of a maximal torus in ''G'' is called the 'rank' of ''G''. The rank is well-defined since all maximal tori turn out to be conjugate. For semisimple groups the rank is equal to the number of nodes in the associated Dynkin diagram.

Contents

Examples

Properties

Examples

The unitary group U(''n'') has as a maximal torus the subgroup of all diagonal matrices. That is,
:$T\; =\; left\{mathrm\{diag\}(e^\{i\; heta\_1\},e^\{i\; heta\_2\},cdots,e^\{i\; heta\_n\})\; :\; heta\_j\; in\; mathbb\; R$
ight}.
''T'' is clearly isomorphic to the product of ''n'' circles, so the unitary group U(''n'') has rank ''n''. A maximal torus in the special unitary group SU(''n'') ⊂ U(''n'') is just the intersection of ''T'' and SU(''n'') which is a torus of dimension ''n'' − 1.
A maximal torus in special orthogonal group SO(2''n'') is a given by the set of all simultaneous rotations in ''n'' pairwise orthogonal 2-planes. This is also a maximal torus in the group SO(2''n''+1) where the action fixes the remaining direction. Therefore, both SO(2''n'') and SO(2''n''+1) have rank ''n''. For example, in the rotation group SO(3) the maximal tori are given by rotations about a fixed axis.
The symplectic group Sp(''n'') has rank ''n''. A maximal torus is given by the set of all diagonal matrices whose entries all lie in a fixed complex subalgebra of 'H'.

Properties

Let ''G'' be a compact, connected Lie group and let $mathfrak\; g$ be the Lie algebra of ''G''.

★ A maximal torus in a ''G'' is a maximal abelian subgroup, but the converse need not hold.

★ The maximal tori in ''G'' are exactly the Lie subgroups corresponding to the maximal abelian subalgebras of $mathfrak\; g$ (cf. Cartan subalgebra)

★ Given a maximal torus ''T'' in ''G'', every element ''g'' ∈ ''G'' is conjugate to an element in ''T''.

★ Since the conjugate of a maximal torus is a maximal torus, every element of ''G'' lies in some maximal torus.

★ All maximal tori in ''G'' are conjugate. Therefore, the maximal tori form a single conjugacy class among the subgroups of ''G''.

★ It follows that the dimensions of all maximal tori are the same. This dimension is the rank of ''G''.

★ If ''G'' has dimension ''n'' and rank ''r'' then ''n'' − ''r'' is even.
Fix a maximal torus ''T'' in ''G''. The Weyl group of ''G'' can be defined as the normalizer of ''T'' modulo the centralizer of ''T''. That is, $W\; =\; N\_G(T)/C\_G(T)$. The representation theory of ''G'' is essentially determined by ''T'' and ''W''.

★ The Weyl group acts by (inner) automorphisms on ''T'' (and it's Lie algebra).

★ The centralizer of ''T'' in ''G'' is equal to ''T'', so the Weyl group is equal to ''N''(''T'')/''T''.

★ The identity component of the normalizer of ''T'' is also equal ''T''. The Weyl group is therefore equal to the component group of ''N''(''T'').

★ The normalizer of ''T'' is closed, so the Weyl group is finite

★ Two elements in ''T'' are conjugate if and only if they are conjugate by an element of ''W''. That is, the conjugacy classes of ''G'' intersect ''T'' in a Weyl orbit.

★ The space of conjugacy classes in ''G'' is diffeomorphic to the orbit space ''T''/''W''.