In mathematics, the split-octonions are an 8-dimensional nonassociative algebra over the real numbers. Unlike the standard octonions, they contain non-zero elements which are non-invertible. Also the signatures of their quadratic forms differ: the split-octonions have a split signature (4,4) whereas the octonions have a positive-definite signature (8,0).
Up to isomorphism, the octonions and the split-octonions are the only two 8-dimensional composition algebras over the real numbers. They are also the only two octonion algebras over the real numbers. Split-octonion algebras analogous to the split-octonions can be defined over any field.
The octonions and the split-octonions can be obtained from the Cayley–Dickson construction by defining a multiplication on pairs of quaternions. We introduce a new imaginary unit ℓ and write a pair of quaternions (a, b) in the form a + ℓb. The product is defined by the rule:[1]
(a+\ellb)(c+\elld)=(ac+λ\bardb)+\ell(da+b\barc)
λ=\ell2.
A basis for the split-octonions is given by the set
\{ 1, i, j, k, \ell, \elli, \ellj, \ellk \}
Every split-octonion
x
x=x0+x1i+x2j+x3k+x4\ell+x5\elli+x6\ellj+x7\ellk,
xa
By linearity, multiplication of split-octonions is completely determined by the following multiplication table:
| multiplier | ||||||||||
| ! width="30pt" | ! width="30pt" | 1 | i | j | k | \ell | \elli | \ellj | \ellk | |
| multiplicand | 1 | 1 | i | j | k | \ell | \elli | \ellj | \ellk | |
|---|---|---|---|---|---|---|---|---|---|---|
i | i | -1 | k | -j | -\elli | \ell | -\ellk | \ellj | ||
j | j | -k | -1 | i | -\ellj | \ellk | \ell | -\elli | ||
k | k | j | -i | -1 | -\ellk | -\ellj | \elli | \ell | ||
\ell | \ell | \elli | \ellj | \ellk | 1 | i | j | k | ||
\elli | \elli | -\ell | -\ellk | \ellj | -i | 1 | k | -j | ||
\ellj | \ellj | \ellk | -\ell | -\elli | -j | -k | 1 | i | ||
\ellk | \ellk | -\ellj | \elli | -\ell | -k | j | -i | 1 | ||
A convenient mnemonic is given by the diagram at the right, which represents the multiplication table for the split-octonions. This one is derived from its parent octonion (one of 480 possible), which is defined by:
eiej=-\deltaije0+\varepsilonijkek,
where
\deltaij
\varepsilonijk
+1
ijk=123,154,176,264,257,374,365,
eie0=e0ei=ei;e0e0=e0,
with
e0
i,j,k=1...7.
The red arrows indicate possible direction reversals imposed by negating the lower right quadrant of the parent creating a split octonion with this multiplication table.
The conjugate of a split-octonion x is given by
\barx=x0-x1i-x2j-x3k-x4\ell-x5\elli-x6\ellj-x7\ellk,
The quadratic form on x is given by
N(x)=\barxx=
| 2 | |
| (x | |
| 0 |
+
| 2 | |
| x | |
| 1 |
+
| 2 | |
| x | |
| 2 |
+
| 2) | |
| x | |
| 3 |
-
| 2 | |
| (x | |
| 4 |
+
| 2 | |
| x | |
| 5 |
+
| 2 | |
| x | |
| 6 |
+
| 2) | |
| x | |
| 7 |
.
This quadratic form N(x) is an isotropic quadratic form since there are non-zero split-octonions x with N(x) = 0. With N, the split-octonions form a pseudo-Euclidean space of eight dimensions over R, sometimes written R4,4 to denote the signature of the quadratic form.
If N(x) ≠ 0, then x has a (two-sided) multiplicative inverse x-1 given by
x-1=N(x)-1{\barx}.
The split-octonions, like the octonions, are noncommutative and nonassociative. Also like the octonions, they form a composition algebra since the quadratic form N is multiplicative. That is,
N(xy)=N(x)N(y).
The automorphism group of the split-octonions is a 14-dimensional Lie group, the split real form of the exceptional simple Lie group G2.
Since the split-octonions are nonassociative they cannot be represented by ordinary matrices (matrix multiplication is always associative). Zorn found a way to represent them as "matrices" containing both scalars and vectors using a modified version of matrix multiplication.[2] Specifically, define a vector-matrix to be a 2×2 matrix of the form[3] [4] [5] [6]
\begin{bmatrix}a&v\ w&b\end{bmatrix},
\begin{bmatrix}a&v\ w&b\end{bmatrix}\begin{bmatrix}a'&v'\ w'&b'\end{bmatrix}=\begin{bmatrix}aa'+v ⋅ w'&av'+b'v+w x w'\ a'w+bw'-v x v'&bb'+v' ⋅ w\end{bmatrix}
Define the "determinant" of a vector-matrix by the rule
\det\begin{bmatrix}a&v\ w&b\end{bmatrix}=ab-v ⋅ w
\det(AB)=\det(A)\det(B).
Zorn's vector-matrix algebra is, in fact, isomorphic to the algebra of split-octonions. Write an octonion
x
x=(a+v)+\ell(b+w)
a
b
x\mapsto\phi(x)=\begin{bmatrix}a+b&v+w\ -v+w&a-b\end{bmatrix}.
N(x)=\det(\phi(x))
Split-octonions are used in the description of physical law. For example: