Cayley–Dickson construction

Idea

The Cayley-Dickson construction or Cayley-Dickson double (Dickson 1919, (6)) takes a real star-algebra $A$ to a new real star-algebra whose elements are pairs of elements of $A$, in generalization of how the complex numbers arise as a doubling of the real numbers.

When iteratively applied to the real numbers, regarded as a star-algebra with trivial involution, the Cayley-Dickson construction yields, consecutively, the complex numbers, then the quaternions, then the octonions (thus all four real normed division algebras), then the sedenions, …

Definition

Let $A$ be an possibly nonassociative star-algebra over the field $\mathbb{R}$ of real numbers: an algebra equipped with an involution $\overline(-) \colon x \mapsto \overline{x}$ which is an antiautomorphism. (Actually, $\mathbb{R}$ could be replaced by any commutative ring in the definitions, although some properties may depend on this ring.)

Definition in components

(Dickson 1919, (6))

Definition by generators and relations

(Baez 02, second half of 2.2)

Equivalence of the definitions

Properties

The map $a\mapsto (a,0)$ is a monomorphism $A\to A^2$. If $A$ is unital with unit $1$ then $A^2$ is unital with unit $(1,0)$. In the unital case, the element $\mathrm{i} \coloneqq (0,1)$ has the property $\mathrm{i}^2 = -1 \coloneqq (-1,0)$, and we may write $(a,b)$ as $a + b \mathrm{i}$ (while $a + \mathrm{i} b = (a,\overline{b})$). For this reason, we may write $A[\mathrm{i}]$ in place of $A^2$, at least when $A$ is unital.

Generally speaking, the double $A^2$ of an algebra $A$ has a nice property iff $A$ is one level nicer. For simplicity, assume that $A$ is unital (so that $\mathbb{R}$ is a subalgebra). Since $\overline{\mathrm{i}} = -\mathrm{i}$, we see that the involution on $A^2$ is trivial iff the involution on $A$ is trivial and $A$ further has $2 = 0$. Since $\mathrm{i} a = \overline{a} \mathrm{i}$, $A^2$ is commutative iff $A$ is commutative and the involution in $A$ is trivial. Since $a (b \mathrm{i}) = (b a) \mathrm{i}$, $A^2$ is associative iff $A$ is associative and commutative. Finally, $A^2$ is alternative iff $A$ is associative (and hence also alternative).

Examples

The standard example is the sequence of consecutive doubles starting with $\mathbb{R}$ itself (with the identity map as involution); these are the Cayley–Dickson algebras: the real numbers $\mathbb{R}$, the complex numbers $\mathbb{C}$, the quaternions $\mathbb{H}$, the octonions (or Cayley numbers) $\mathbb{O}$,

These are the real normed division algebras

The diagram on the right shows a basis of imaginary octonions obtained via Cayley-Dickson doubling from a standard basis $\{i,j,k\}$ of imaginary quaternions.

Next, the CD-double of the octonions is the sedenions $\mathbb{S}$, etc. , followed by further algebras which are not division algebras.
All of these algebras are power-associative, flexible, and unital, and have all inverse elements; the subalgebra with $\overline{x} = x$ is always just $\mathbb{R}$.

Cayley-Dickson-Albert construction

The Cayley-Dickson construction described above was slightly generalized in Section 5 of Albert (1942), where the multiplication is further modified by a parameter $\gamma$ in the ground field. This process constructs an algebra $A^{\gamma}$ starting from a unital algebra $A$ of order $n$ over a field $F$ endowed with an involution $J:A\to A$ over $F$ such that for all $x\in A$:

• $x+ J(x) \in F$,

• $x J(x) = J(x) x \in F$.

To construct $A^{\gamma}$, one chooses a parameter $\gamma\in F$, and on the vector space $A\oplus A$ one defines a product

and an involution $K$ on $A^{\gamma}$ as

In particular, for $F=\mathbb{R}$ this process allows to get the split- variants of the real division algebra, cf.:

• split-complex numbers

• split quaternions

• split octonions

Higher algebra

Albuquerque & Majid (1999) describe the Cayley-Dickson process from a different point of view. The quaternions, and octonions are realized as $\mathbb{Z}_2^n$ group algebras over the reals twisted by a group $n$-cocycle $\omega\in Z^n(\mathbb{Z}_2^n,\mathbb{R}^{\times})$, for $n=2,3$, respectively.

In more detail, the quaternions are described as the group algebra $\mathbb{R}[\mathbb{Z}_2\times\mathbb{Z}_2]$ where the group multiplication is twisted by a cocycle $\omega(g,h)$. The 2-cocycle condition of such a function implies that the quaternions are associative. On the other hand, the octonions are realized as a group algebra $\mathbb{R}[\mathbb{Z}_2\times\mathbb{Z}_2\times\mathbb{Z}_2 ]$ where the function $\omega(g,h)$ twisting the multiplication is no longer a 2-cocycle. One of the effects of this is that the octonions are no longer associative or, rather, that they satisfy a nontrivial associativity condition, in the sense of a quasi-Hopf algebra. This nontrivial associativity condition is witnessed by a group $3$-cocycle in $Z^3(\mathbb{Z}_2\times \mathbb{Z}_2\times \mathbb{Z}_2, \mathbb{R}^{\times})$. Notably, this $3$-cocycle turns out to be a $3$-coboundary, so that its cohomology class is trivial.

This point of view also clarifies the common claim that algebras in the Cayley-Dickson process lose “nice” properties after more iterations. Rather, a more precise claim is that these nice properties are weakened. In the case of the octonions, these are better regarded as associative up to a nontrivial cocycle.

This highlights that a more suitable point of view to study the algebras arising in the Cayley-Dickson process is higher algebra. As noted in e.g. (p.8 of Baez (2002)), the octonions are indeed associative, when viewed as a monoid object internal to the tensor category which is the fusion category of $\mathbb{Z}_2^3$-graded real vector spaces with nontrivial associator defined by the twisting $3$-cocycle.

This seems to suggest a pattern regarding the rest of the $2^n$-gons, as of now unproven(?). For instance, the sedenions could be realized as a twist of the group algebra $\mathbb{R}[\mathbb{Z}_2^4]$ by a 4-cocycle $Z^4(\mathbb{Z}_2^4,\mathbb{R}^{\times})$, and as such would have fewer nice properties as a 1-algebra. Yet as a higher algebra it would retain its nice properties: it would correspond to the fusion 2-category of $\mathbb{Z}_2^4$-graded 2-vector spaces twisted by a group 4-cocycle.

Related concepts

• composition algebra

References

Named after Arthur Cayley and Leonard Dickson.

The original article:

• Leonard Dickson, On Quaternions and Their Generalization and the History of the Eight Square Theorem,

  Annals of Mathematics, Second Series, Vol. 20, No. 3 (Mar., 1919), pp. 155-171 (jstor:1967865)

Review and introduction:

• M M Postnikov, Lectures on geometry, Semester V: Lie groups and Lie algebras, Lec. 14 (russian and english editions)

• John Baez, The Cayley–Dickson construction, in The octonions, Bull. Amer. Math. Soc. 39 (2002), 145-205, doi

• John Baez, This Week’s Finds — Week 59

• Tevian Dray, Corinne Manogue, Section 5.1 of: The Geomety of Octonions, World Scientific 2015 (doi:10.1142/8456)

See also

• Wikipedia, Cayley–Dickson construction

More:

• Daniel K. Biss, Daniel Dugger, Daniel Isaksen, Large annihilators in Cayley-Dickson algebras, Communications in Algebra 36 (2), 632-664, 2008 (arxiv:math/0511691)

• Daniel K. Biss, Daniel Christensen, Daniel Dugger, Daniel Isaksen, Large annihilators in Cayley-Dickson algebras II, Boletin de la Sociedad Matematica Mexicana (3) 13(2) (2007), 269-292 (arxiv:math/0702075)

• Daniel K. Biss, Daniel Christensen, Daniel Dugger, Daniel Isaksen, Eigentheory of Cayley-Dickson algebras, Forum Mathematicum 21(5) (2009), 833-851 (arxiv:0905.2987)

On the generalization of the Cayley-Dickson construction:

• Abraham Adrian Albert, Quadratic forms permitting composition, Ann. of Math. (2) 43 (1942), 161–177. (doi)

On the Cayley-Dickson construction in terms of quasi-Hopf algebras:

• Helena Albuquerque, Shahn Majid. Quasialgebra Structure of the Octonions. Journal of Algebra Volume 220, Issue 1, 1 October 1999, Pages 188-224. (doi)