Contents

Split-octonion

Definition[edit]

Cayley–Dickson construction[edit]

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]

${\displaystyle (a+\ell b)(c+\ell d)=(ac+\lambda {\bar {d}}b)+\ell (da+b{\bar {c}})}$

where

${\displaystyle \lambda =\ell ^{2}.}$

Ifλ is chosen to be −1, we get the octonions. If, instead, it is taken to be +1 we get the split-octonions. One can also obtain the split-octonions via a Cayley–Dickson doubling of the split-quaternions. Here either choice of λ (±1) gives the split-octonions.

Multiplication table[edit]

Abasis for the split-octonions is given by the set ${\displaystyle \{\ 1,\ i,\ j,\ k,\ \ell ,\ \ell i,\ \ell j,\ \ell k\ \}}$.

Every split-octonion ${\displaystyle x}$ can be written as a linear combination of the basis elements,

${\displaystyle x=x_{0}+x_{1}\,i+x_{2}\,j+x_{3}\,k+x_{4}\,\ell +x_{5}\,\ell i+x_{6}\,\ell j+x_{7}\,\ell k,}$

with real coefficients ${\displaystyle x_{a}}$.

By linearity, multiplication of split-octonions is completely determined by the following multiplication table:

		multiplier
		${\displaystyle 1}$	${\displaystyle i}$	${\displaystyle j}$	${\displaystyle k}$	${\displaystyle \ell }$	${\displaystyle \ell i}$	${\displaystyle \ell j}$	${\displaystyle \ell k}$
multiplicand	${\displaystyle 1}$	${\displaystyle 1}$	${\displaystyle i}$	${\displaystyle j}$	${\displaystyle k}$	${\displaystyle \ell }$	${\displaystyle \ell i}$	${\displaystyle \ell j}$	${\displaystyle \ell k}$
	${\displaystyle i}$	${\displaystyle i}$	${\displaystyle -1}$	${\displaystyle k}$	${\displaystyle -j}$	${\displaystyle -\ell i}$	${\displaystyle \ell }$	${\displaystyle -\ell k}$	${\displaystyle \ell j}$
	${\displaystyle j}$	${\displaystyle j}$	${\displaystyle -k}$	${\displaystyle -1}$	${\displaystyle i}$	${\displaystyle -\ell j}$	${\displaystyle \ell k}$	${\displaystyle \ell }$	${\displaystyle -\ell i}$
	${\displaystyle k}$	${\displaystyle k}$	${\displaystyle j}$	${\displaystyle -i}$	${\displaystyle -1}$	${\displaystyle -\ell k}$	${\displaystyle -\ell j}$	${\displaystyle \ell i}$	${\displaystyle \ell }$
	${\displaystyle \ell }$	${\displaystyle \ell }$	${\displaystyle \ell i}$	${\displaystyle \ell j}$	${\displaystyle \ell k}$	${\displaystyle 1}$	${\displaystyle i}$	${\displaystyle j}$	${\displaystyle k}$
	${\displaystyle \ell i}$	${\displaystyle \ell i}$	${\displaystyle -\ell }$	${\displaystyle -\ell k}$	${\displaystyle \ell j}$	${\displaystyle -i}$	${\displaystyle 1}$	${\displaystyle k}$	${\displaystyle -j}$
	${\displaystyle \ell j}$	${\displaystyle \ell j}$	${\displaystyle \ell k}$	${\displaystyle -\ell }$	${\displaystyle -\ell i}$	${\displaystyle -j}$	${\displaystyle -k}$	${\displaystyle 1}$	${\displaystyle i}$
	${\displaystyle \ell k}$	${\displaystyle \ell k}$	${\displaystyle -\ell j}$	${\displaystyle \ell i}$	${\displaystyle -\ell }$	${\displaystyle -k}$	${\displaystyle j}$	${\displaystyle -i}$	${\displaystyle 1}$

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:

${\displaystyle e_{i}e_{j}=-\delta _{ij}e_{0}+\varepsilon _{ijk}e_{k},\,}$

where ${\displaystyle \delta _{ij}}$ is the Kronecker delta and ${\displaystyle \varepsilon _{ijk}}$ is the Levi-Civita symbol with value ${\displaystyle +1}$ when ${\displaystyle ijk=123,154,176,264,257,374,365,}$ and:

${\displaystyle e_{i}e_{0}=e_{0}e_{i}=e_{i};\,\,\,\,e_{0}e_{0}=e_{0},}$

with ${\displaystyle e_{0}}$ the scalar element, and ${\displaystyle i,j,k=1...7.}$

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.

Conjugate, norm and inverse[edit]

The conjugate of a split-octonion x is given by

${\displaystyle {\bar {x}}=x_{0}-x_{1}\,i-x_{2}\,j-x_{3}\,k-x_{4}\,\ell -x_{5}\,\ell i-x_{6}\,\ell j-x_{7}\,\ell k,}$

just as for the octonions.

The quadratic formonx is given by

${\displaystyle N($x)={\bar {x}}x=(x_{0}^{2}+x_{1}^{2}+x_{2}^{2}+x_{3}^{2})-(x_{4}^{2}+x_{5}^{2}+x_{6}^{2}+x_{7}^{2}).}

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 R^4,4 to denote the signature of the quadratic form.

IfN(x) ≠ 0, then x has a (two-sided) multiplicative inverse x⁻¹ given by

${\displaystyle x^{-1}=N($x)^{-1}{\bar {x}}.}

Properties[edit]

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,

${\displaystyle N($xy)=N(x)N(y).}

The split-octonions satisfy the Moufang identities and so form an alternative algebra. Therefore, by Artin's theorem, the subalgebra generated by any two elements is associative. The set of all invertible elements (i.e. those elements for which N(x) ≠ 0) form a Moufang loop.

The automorphism group of the split-octonions is a 14-dimensional Lie group, the split real form of the exceptional simple Lie group G₂.

Zorn's vector-matrix algebra[edit]

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]

${\displaystyle {\begin{bmatrix}a&\mathbf {v} \\\mathbf {w} &b\end{bmatrix}},}$

where a and b are real numbers and v and w are vectors in R³. Define multiplication of these matrices by the rule

${\displaystyle {\begin{bmatrix}a&\mathbf {v} \\\mathbf {w} &b\end{bmatrix}}{\begin{bmatrix}a'&\mathbf {v} '\\\mathbf {w} '&b'\end{bmatrix}}={\begin{bmatrix}aa'+\mathbf {v} \cdot \mathbf {w} '&a\mathbf {v} '+b'\mathbf {v} +\mathbf {w} \times \mathbf {w} '\\a'\mathbf {w} +b\mathbf {w} '-\mathbf {v} \times \mathbf {v} '&bb'+\mathbf {v} '\cdot \mathbf {w} \end{bmatrix}}}$

where · and × are the ordinary dot product and cross product of 3-vectors. With addition and scalar multiplication defined as usual the set of all such matrices forms a nonassociative unital 8-dimensional algebra over the reals, called Zorn's vector-matrix algebra.

Define the "determinant" of a vector-matrix by the rule

${\displaystyle \det {\begin{bmatrix}a&\mathbf {v} \\\mathbf {w} &b\end{bmatrix}}=ab-\mathbf {v} \cdot \mathbf {w} }$.

This determinant is a quadratic form on Zorn's algebra which satisfies the composition rule:

${\displaystyle \det($AB)=\det(A)\det(B).\,}

Zorn's vector-matrix algebra is, in fact, isomorphic to the algebra of split-octonions. Write an octonion ${\displaystyle x}$ in the form

${\displaystyle x=(a+\mathbf {v} )+\ell (b+\mathbf {w} )}$

where ${\displaystyle a}$ and ${\displaystyle b}$ are real numbers and v and w are pure imaginary quaternions regarded as vectors in R³. The isomorphism from the split-octonions to Zorn's algebra is given by

${\displaystyle x\mapsto \phi ($x)={\begin{bmatrix}a+b&\mathbf {v} +\mathbf {w} \\-\mathbf {v} +\mathbf {w} &a-b\end{bmatrix}}.}

This isomorphism preserves the norm since ${\displaystyle N($x)=\det(\phi (x))} .

Applications[edit]

Split-octonions are used in the description of physical law. For example:

• The Dirac equation in physics (the equation of motion of a free spin 1/2 particle, like e.g. an electron or a proton) can be expressed on native split-octonion arithmetic.^[7]
• Supersymmetric quantum mechanics has an octonionic extension.^[8]
• The Zorn-based split-octonion algebra can be used in modeling local gauge symmetric SU(3) quantum chromodynamics.^[9]
• The problem of a ball rolling without slipping on a ball of radius 3 times as large has the split real form of the exceptional group G₂ as its symmetry group, owing to the fact that this problem can be described using split-octonions.^[10]

References[edit]

Further reading[edit]

• R. Foot & G. C. Joshi (1990) "Nonstandard signature of spacetime, superstrings, and the split composition algebras", Letters in Mathematical Physics 19: 65–71
• Harvey, F. Reese (1990). Spinors and Calibrations. San Diego: Academic Press. ISBN 0-12-329650-1.
• Nash, Patrick L (1990) "On the structure of the split octonion algebra", Il Nuovo Cimento B 105(1): 31–41. doi:10.1007/BF02723550
• Springer, T. A.; F. D. Veldkamp (2000). Octonions, Jordan Algebras and Exceptional Groups. Springer-Verlag. ISBN 3-540-66337-1.