Middle-associative elements of magma form submagma

Statement

Let ${\displaystyle (S,*)}$ be a magma (a set ${\displaystyle S}$ with binary operation ${\displaystyle *}$). Call an element ${\displaystyle b\in S}$ a middle-associative element if the following holds:

${\displaystyle a*(b*c)=(a*b)*c\ \forall \ a,c\in S}$

Then, the set of middle-associative elements of ${\displaystyle S}$ forms a submagma of ${\displaystyle S}$.

Related facts

• Left-associative elements of magma form submagma
• Right-associative elements of magma form submagma

All these proofs make crucial use of the associativity pentagon: the pentagon describing the relation between the five different ways of associating a product of length four.

Proof

Proof idea

The idea behind the proof is the associativity pentagon, which states that the five different ways of parenthesizing an expression of length four form a cyclic pentagon, with each expression related to exactly two others via a single application of the associativity law. In order to move along one edge of the pentagon, we instead move along the path comprising the remaining four edges, and use the fact that each step there is allowed because one of ${\displaystyle b_{1}}$ and ${\displaystyle b_{2}}$ is the middle term in each of the applications of the law.

Proof of (1)

Given: A magma ${\displaystyle (S,*)}$, two middle-associative elements ${\displaystyle b_{1},b_{2}\in S}$

To prove: ${\displaystyle b_{1}*b_{2}}$ is left-associative

Proof: We need to show that, for any ${\displaystyle a,c\in S}$, we have:

${\displaystyle (a*(b_{1}*b_{2}))*c=a*((b_{1}*b_{2})*c)}$

Let's do this. Start with the left side and proceed as follows:

${\displaystyle (a*(b_{1}*b_{2}))*c=((a*b_{1})*b_{2})*c=(a*b_{1})*(b_{2}*c)=a*(b_{1}*(b_{2}*c))=a*((b_{1}*b_{2})*c)}$.