Commutative magma

In mathematics, it can be shown that there exist magmas that are commutative but not associative. A simple example of such a magma is given by considering the children's game of rock, paper, scissors.

Let ${\displaystyle M:=\{r,p,s\}}$ and consider the binary operation ${\displaystyle \cdot :M\times M\to M}$ defined, loosely inspired by the rock-paper-scissors game, as follows:

${\displaystyle r\cdot p=p\cdot r=p}$   "paper beats rock";

${\displaystyle p\cdot s=s\cdot p=s}$   "scissors beat paper";

${\displaystyle r\cdot s=s\cdot r=r}$   "rock beats scissors";

${\displaystyle r\cdot r=r}$   "rock ties with rock";

${\displaystyle p\cdot p=p}$   "paper ties with paper";

${\displaystyle s\cdot s=s}$   "scissors tie with scissors".

By definition, the magma ${\displaystyle (M,\cdot )}$ is commutative, but it is also non-associative, as the following shows:

${\displaystyle r\cdot (p\cdot s)=r\cdot s=r}$

but

${\displaystyle (r\cdot p)\cdot s=p\cdot s=s.}$

Using the above example, one can construct a commutative non-associative algebra over a field ${\displaystyle K}$: take ${\displaystyle A}$ to be the three-dimensional vector space over ${\displaystyle K}$ whose elements are written in the form

${\displaystyle (x,y,z)=xr+yp+zs}$,

for ${\displaystyle x,y,z\in K}$. Vector addition and scalar multiplication are defined component-wise, and vectors are multiplied using the above rules for multiplying the elements ${\displaystyle r,p}$ and ${\displaystyle s}$. The set

${\displaystyle \{(1,0,0),(0,1,0),(0,0,1)\}}$ i.e. ${\displaystyle \{r,p,s\}}$

forms a basis for the algebra ${\displaystyle A}$. As before, vector multiplication in ${\displaystyle A}$ is commutative, but not associative.