In mathematics, the Jacobi identity is a property of a binary operation that describes how the order of evaluation, the placement of parentheses in a multiple product, affects the result of the operation. By contrast, for operations with the associative property, any order of evaluation gives the same result (parentheses in a multiple product are not needed). The identity is named after the German mathematician Carl Gustav Jacob Jacobi. He derived the Jacobi identity for Poisson brackets in his 1862 paper on differential equations.[1] [2]
a x b
[a,b]
Let
+
x
0
+
x x (y x z) + y x (z x x) + z x (x x y) = 0.
Notice the pattern in the variables on the left side of this identity. In each subsequent expression of the form
a x (b x c)
x
y
z
x\mapstoy\mapstoz\mapstox
(x,y,z)
(y,z,x)
(z,x,y)
(x,y,z)
The simplest informative example of a Lie algebra is constructed from the (associative) ring of
n x n
X x Y
[X,Y]=XY-YX.
In that notation, the Jacobi identity is:
[X,[Y,Z]]+[Y,[Z,X]]+[Z,[X,Y]] = 0
More generally, if is an associative algebra and is a subspace of that is closed under the bracket operation:
[X,Y]=XY-YX
X,Y\inV
[X,Y]
XY-YX
[X,Y]=-[Y,X]
[[X,Y],Z]=[X,[Y,Z]]-[Y,[X,Z]]~.
If
[X,Z]
There is also a plethora of graded Jacobi identities involving anticommutators
\{X,Y\}
[\{X,Y\},Z]+[\{Y,Z\},X]+[\{Z,X\},Y]=0, [\{X,Y\},Z]+\{[Z,Y],X\}+\{[Z, X],Y\}=0.
See also: Lie bracket of vector fields and Baker–Campbell–Hausdorff formula.
Most common examples of the Jacobi identity come from the bracket multiplication
[x,y]
[x,[y,z]]+[z,[x,y]]+[y,[z,x]]=0.
\operatorname{ad}x:y\mapsto[x,y]
\operatorname{ad}x[y,z]=[\operatorname{ad}xy,z]+[y,\operatorname{ad}xz].
Thus, the Jacobi identity for Lie algebras states that the action of any element on the algebra is a derivation. That form of the Jacobi identity is also used to define the notion of Leibniz algebra.
Another rearrangement shows that the Jacobi identity is equivalent to the following identity between the operators of the adjoint representation:
\operatorname{ad}[x,y]=[\operatorname{ad}x,\operatorname{ad}y].
There, the bracket on the left side is the operation of the original algebra, the bracket on the right is the commutator of the composition of operators, and the identity states that the
ad
[x,[y,[z,w]]]+[y,[x,[w,z]]]+[z,[w,[x,y]]]+[w,[z,[y,x]]]=0.
[X,[Y,Z]]=[[X,Y],Z]+[Y,[X,Z]]
X,Y
[X,Y]
Y
l{L}XY