Right-associative elements of loop form subgroup

Statement

Suppose ${\displaystyle (L,*)}$ is an algebra loop. Then, the set of right-associative elements of ${\displaystyle L}$ is nonempty and forms a subgroup of ${\displaystyle L}$. This subgroup is termed the right kernel of ${\displaystyle L}$ or the right-associative center of ${\displaystyle L}$.

Definitions used

Right-associative element

An element ${\displaystyle c\in L}$ is termed right-associative if, for all ${\displaystyle a,b\in L}$, we have:

${\displaystyle (a*b)*c=a*(b*c)}$.

Related facts

• Left-associative elements of loop form subgroup: Note that the proofs are identical and the facts can be deduced from each other using the opposite magma construction.

Facts used

1. Right-associative elements of magma form submagma
2. Monoid where every element is left-invertible equals group

Proof

Given: A loop ${\displaystyle (L,*)}$ with identity element ${\displaystyle e}$. ${\displaystyle S}$ is the set of right-associative elements of ${\displaystyle L}$.

To prove: ${\displaystyle S}$ is a subgroup of ${\displaystyle L}$. More explicitly, ${\displaystyle (S,*)}$ is a group with identity element ${\displaystyle e}$.

Proof:

Step no.	Assertion/construction	Facts used	Given data used	Previous steps used	Explanation
1	${\displaystyle (S,*)}$ is a monoid with identity element ${\displaystyle e}$.	Fact (1)	${\displaystyle (L,*)}$ has identity element ${\displaystyle e}$		Follows directly from Fact (1).
2	For any ${\displaystyle a\in S}$, there is a left inverse of ${\displaystyle a}$ in ${\displaystyle L}$, i.e., an element ${\displaystyle b\in L}$ such that ${\displaystyle b*a=e}$.		${\displaystyle L}$ is a loop
3	For any ${\displaystyle a\in S}$, the left inverse ${\displaystyle b}$ constructed in Step (2) is in ${\displaystyle S}$. In other words, for any ${\displaystyle c,d\in S}$, we have ${\displaystyle (c*d)*b=c*(d*b)}$.		${\displaystyle L}$ is a loop, so any equation ${\displaystyle x*a=z}$ has a unique solution for ${\displaystyle x}$.	Step (2)	Using right-associativity of ${\displaystyle a}$, we get: ${\displaystyle ((c*d)*b)*a=(c*d)*(b*a)=(c*d)*e=c*d}$. Similarly, ${\displaystyle (c*(d*b))*a=c*((d*b)*a)=c*(d*(b*a))=c*(d*e)=c*d}$. Thus, ${\displaystyle ((c*d)*b)*a=(c*(d*b))*a=c*d}$. Thus, both ${\displaystyle (c*d)*b}$ and ${\displaystyle c*(d*b)}$ are solutions for ${\displaystyle x}$ to ${\displaystyle x*a=c*d}$, hence they are equal.
4	${\displaystyle (S,*)}$ is a monoid with identity element ${\displaystyle e}$ in which every element has a left inverse.			Steps (1), (3)	Step-combination direct
5	${\displaystyle (S,*)}$ is a group with identity element ${\displaystyle e}$, completing the proof.	Fact (2)		Step (4)	Step-fact combination direct.