Jordan algebra

In mathematics, a Jordan algebra is defined in abstract algebra as an algebra over a field with multiplication satisfying the following axioms:

$x y = y x$ (commutative law)
$(x y)(x x) = x (y (x x))$ (Jordan identity)

Jordan algebras were first introduced by Pascual Jordan in quantum mechanics.

Given an associative algebra $A$ (not of characteristic 2), one can construct a Jordan algebra $A +$ with the same underlying addition, and a new multiplication $(x . y)$ as follows.

$(x .y) = {xy+yx \over 2}$ .

If $A$ has an involution, then the involution fixes elements of the form

(x y + y x) / 2

Thus the set of all elements fixed by the involution form a subalgebra of $A +$ .

A Jordan algebra that is isomorphic to an algebra of the form $A +$ is known as a special Jordan algebra. Otherwise it is an exceptional Jordan algebra.

Examples

The set of self-adjoint real, complex, or quaternionic matrices with multiplication

(x y + y x) / 2

form a special Jordan algebra.

The set of 3×3 self-adjoint matrices over the octonions again with multiplication

(x y + y x) / 2

Despite the similarity to the previous example, this is an exceptional Jordan algebra. (The octonions are not an associative algebra.)

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