Exponent three implies 2-Engel for groups

Statement

Any group of exponent equal to three must be a 2-Engel group (also known as a Levi group).

Related facts

Not true for Lie rings

Exponent three not implies 2-Engel for Lie rings

Converse of sorts

This converse says that although a 2-Engel group need not have exponent three, the extent to which 2-Engel differs from class two is captured by exponent three:

2-Engel group implies third member of lower central series has exponent dividing three
2-Engel Lie ring implies third member of lower central series is in 3-torsion

Applications

Exponent three implies class three for Lie rings

Proof

We use the definition that a group is a 2-Engel group if and only if an two conjugates commute.

Proof using left action convention

In this convention, the conjugate of $a$ by $b$ is denoted $b a b^{- 1}$ and the commutator $[a, b]$ is defined as $a b a^{- 1} b^{- 1}$ .

Given: A group $G$ of exponent three, elements $x, y \in G$

To prove: $[x, y x y^{- 1}]$ is the identity element.

Proof: We have:

$[x, y x y^{- 1}] = x y x y^{- 1} x^{- 1} (y x y^{- 1})^{- 1}$

This simplifies to:

$x y x y^{- 1} x^{- 1} y x^{- 1} y^{- 1}$

Rewrite the right most $y^{- 1}$ as $y^{2} = y y$ , using that $y^{3}$ is the identity element, and get:

$x y x y^{- 1} x^{- 1} y x^{- 1} y y$

We now see two adjacent occurrences of $x^{- 1} y$ , so we have a $(x^{- 1} y)^{2}$ in the expression. Using that $(x^{- 1} y)^{3}$ is the identity element, we obtain that $(x^{- 1} y)^{2} = (x^{- 1} y)^{- 1} = y^{- 1} x$ . We get:

$x y x y^{- 1} (y^{- 1} x) y$

We now see two adjacent occurrences of $y^{- 1}$ , giving $y^{- 2}$ , which simplifies to $y$ , again using that $y^{3}$ is the identity element. We get:

$x y x y x y$

We now simplify this to the identity element using that $(x y)^{3}$ is the identity element, and we are done.