Jordan Pair

In algebra, a triple system (or ternar) is a vector space ''V'' over a field F together with a F-trilinear map
:$(\cdot,\cdot,\cdot) \colon V\times V \times V\to V.$
The most important examples are Lie triple systems and Jordan triple systems. They were introduced by Nathan Jacobson in 1949 to study subspaces of associative algebras closed under triple commutators ''u'', ''v'' ''w''] and triple Commutator, anticommutators . In particular, any Lie algebra defines a Lie triple system and any Jordan algebra defines a Jordan triple system. They are important in the theories of symmetric spaces, particularly Hermitian symmetric spaces and their generalizations (symmetric R-spaces and their noncompact duals).

Lie triple systems

A triple system is said to be a ''Lie triple system'' if the trilinear map, denoted cdot,\cdot,\cdot, satisfies the following identities:
: ,v,w= - ,u,w
: ,v,w+ ,u,v+ ,w,u= 0
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The first two identities abstract the skew symmetry and Jacobi identity for the triple commutator, while the third identity means that the linear map L_''u'',''v'': ''V'' → ''V'', defined by L_''u'',''v''(''w'') = 'u'', ''v'', ''w'' is a derivation of the triple product. The identity also shows that the space k = span is closed under commutator bracket, hence a Lie algebra.

Writing m in place of ''V'', it follows that
:$\mathfrak g := k \oplus\mathfrak m$
can be made into a $\mathbb_2$-graded Lie algebra, the ''standard embedding'' of m, with bracket
: L,u),(M,v)= ( ,ML_, L(v) - M(u)).
The decomposition of g is clearly a symmetric decomposition for this Lie bracket, and hence if ''G'' is a connected Lie group with Lie algebra g and ''K'' is a subgroup with Lie algebra k, then ''G''/''K'' is a symmetric space.

Conversely, given a Lie algebra g with such a symmetric decomposition (i.e., it is the Lie algebra of a symmetric space), the triple bracket ''u'', ''v'' ''w''] makes m into a Lie triple system.

Jordan triple systems

A triple system is said to be a Jordan triple system if the trilinear map, denoted , satisfies the following identities:
:$\ = \$
:$\ = \ + \ -\.$
The first identity abstracts the symmetry of the triple anticommutator, while the second identity means that if L_''u'',''v'':''V''→''V'' is defined by L_''u'',''v''(''y'') = then
: _,L_= L_\circ L_ - L_ \circ L_ = L_-L_
so that the space of linear maps span is closed under commutator bracket, and hence is a Lie algebra g₀.

Any Jordan triple system is a Lie triple system with respect to the product
: ,v,w= \ - \.

A Jordan triple system is said to be positive definite (resp. nondegenerate) if the bilinear form on ''V'' defined by the trace of L_''u'',''v'' is positive definite (resp. nondegenerate). In either case, there is an identification of ''V'' with its dual space, and a corresponding involution on g₀. They induce an involution of
:$V\oplus\mathfrak g_0\oplus V^*$
which in the positive definite case is a Cartan involution. The corresponding symmetric space is a symmetric R-space. It has a noncompact dual given by replacing the Cartan involution by its composite with the involution equal to +1 on g₀ and −1 on ''V'' and ''V''^*. A special case of this construction arises when g₀ preserves a complex structure on ''V''. In this case we obtain dual Hermitian symmetric spaces of compact and noncompact type (the latter being bounded symmetric domains).

Jordan pair

A Jordan pair is a generalization of a Jordan triple system involving two vector spaces ''V''₊ and ''V''₋. The trilinear map is then replaced by a pair of trilinear maps
:$\_+\colon V_-\times S^2V_+ \to V_+$
:$\_-\colon V_+\times S^2V_- \to V_-$
which are often viewed as quadratic maps ''V''₊ → Hom(''V''₋, ''V''₊) and ''V''₋ → Hom(''V''₊, ''V''₋). The other Jordan axiom (apart from symmetry) is likewise replaced by two axioms, one being
:$\_+ = \_+ + \_+ - \_+$
and the other being the analogue with + and − subscripts exchanged.

As in the case of Jordan triple systems, one can define, for ''u'' in ''V''₋ and ''v'' in ''V''₊, a linear map
:$L^+_:V_+\to V_+ \quad\text \quad L^+_(y) = \_+$
and similarly L⁻. The Jordan axioms (apart from symmetry) may then be written
: ^_,L^_= L^_-L^_
which imply that the images of L⁺ and L⁻ are closed under commutator brackets in End(''V''₊) and End(''V''₋). Together they determine a linear map
:$V_+\otimes V_- \to \mathfrak(V_+)\oplus \mathfrak(V_-)$
whose image is a Lie subalgebra $\mathfrak_0$, and the Jordan identities become Jacobi identities for a graded Lie bracket on
:$V_+\oplus \mathfrak g_0\oplus V_-,$
so that conversely, if
:$\mathfrak g = \mathfrak g_ \oplus \mathfrak g_0\oplus \mathfrak g_$
is a graded Lie algebra, then the pair $(\mathfrak g_, \mathfrak g_)$ is a Jordan pair, with brackets
: \_ := X_,Y_Z_].

Jordan triple systems are Jordan pairs with ''V''₊ = ''V''₋ and equal trilinear maps. Another important case occurs when ''V''₊ and ''V''₋ are dual to one another, with dual trilinear maps determined by an element of
:$\mathrm(S^2V_+) \cong S^2V_+^* \otimes S^2V_-^*\cong \mathrm(S^2V_-).$
These arise in particular when $\mathfrak g$ above is semisimple, when the Killing form provides a duality between $\mathfrak g_$ and $\mathfrak g_$.

See also

*Associator
* Quadratic Jordan algebra

References

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* {{citation, last=Tevelev, first= E. , year=2002, url=http://www.emis.de/journals/JLT/vol.12_no.2/9.html, title=Moore-Penrose inverse, parabolic subgroups, and Jordan pairs, journal= Journal of Lie Theory, volume=12, pages=461–481, bibcode= 2001math......1107T , arxiv= math/0101107

Representation theory