Cube map is surjective endomorphism implies abelian: Difference between revisions

This article describes an easy-to-prove fact about basic notions in group theory, that is not very well-known or important in itself
View other elementary non-basic facts
VIEW FACTS USING THIS: directly | directly or indirectly, upto two steps | directly or indirectly, upto three steps|
VIEW: Survey articles about this

Statement

Verbal statement

If the Cube map (?) on a group is an automorphism, then the group is an abelian group.

Statement with symbols

Let ${\displaystyle G}$ be a group such that the map ${\displaystyle \sigma :G\to G}$ defined by ${\displaystyle \sigma (x)=x^{3}}$ is an automorphism. Then, ${\displaystyle G}$ is an abelian group.

Related facts

Applications

• Cube map is endomorphism iff abelian (if order is not a multiple of 3)

Stronger facts for other values

• Inverse map is automorphism iff abelian
• Square map is endomorphism iff abelian

Weaker facts for other values

• nth power map is endomorphism iff abelian (if order is relatively prime to n(n-1))

Facts used

1. Group acts as automorphisms by conjugation: For any ${\displaystyle g\in G}$, the map ${\displaystyle c_{g}=x\mapsto gxg^{-1}}$ is an automorphism of ${\displaystyle G}$.
2. nth power map is automorphism implies (n-1)th power map is endomorphism taking values in the center
3. Square map is endomorphism iff abelian

Proof

Hands-on proof using fact (1)

This proof uses a tabular format for presentation. Provide feedback on tabular proof formats in a survey (opens in new window/tab) | Learn more about tabular proof formats|View all pages on facts with proofs in tabular format

Given: A group ${\displaystyle G}$ such that the map sending ${\displaystyle x}$ to ${\displaystyle x^{3}}$ is an automorphism of ${\displaystyle G}$.

To prove: ${\displaystyle G}$ is abelian.

Proof: We denote by ${\displaystyle c_{g}}$ the map ${\displaystyle x\mapsto gxg^{-1}}$.

Step no.	Assertion	Given data used	Facts used	Previous steps used	Explanation
1	${\displaystyle g^{2}h^{3}=h^{3}g^{2}}$ for all ${\displaystyle g,h\in G}$, i.e., every square commutes with every cube	Cube map is an automorphism, and hence an endomorphism	Fact (1)	--	[SHOW MORE] Consider ${\displaystyle g,h\in G}$. Then, by fact (1), ${\displaystyle c_{g}}$ is an automorphism, so we have: ${\displaystyle \!c_{g}(h^{3})=c_{g}(h)^{3}}$, giving ${\displaystyle gh^{3}g^{-1}=(ghg^{-1})^{3}}$. On the other hand, since the cube map is an endomorphism, we have ${\displaystyle (ghg^{-1})^{3}=g^{3}h^{3}g^{-3}}$. Combining these, we get ${\displaystyle gh^{3}g^{-1}=g^{3}h^{3}g^{-3}}$. Canceling the left-most ${\displaystyle g}$ and the right-most ${\displaystyle g^{-1}}$ and rearranging yields that ${\displaystyle g^{2}h^{3}=h^{3}g^{2}}$.
2	${\displaystyle g^{2}x=xg^{2}}$ for all ${\displaystyle g,x\in G}$	Cube map is an automorphism, hence is bijective	--	Step (1)	[SHOW MORE] Since the cube map is bijective, every element of ${\displaystyle G}$ is a cube. Combining this with step (1) yields that ${\displaystyle g^{2}x=xg^{2}}$ for every ${\displaystyle g,x\in G}$.
3	${\displaystyle g^{2}x^{2}=xgxg}$ for all ${\displaystyle g,x\in G}$	Cube map is an automorphism, hence an endomorphism	--	--	[SHOW MORE] Since the cube map is an endomorphism, we get ${\displaystyle (gx)^{3}=g^{3}x^{3}}$, so expanding and canceling the left-most and right-most terms yields ${\displaystyle xgxg=g^{2}x^{2}}$.
4	We get ${\displaystyle gx=xg}$ for all ${\displaystyle g,x\in G}$.			Steps (2), (3)	[SHOW MORE] Using step (2), we can rewrite ${\displaystyle g^{2}x^{2}}$ as ${\displaystyle xg^{2}x}$. Combining with step (3) yields that ${\displaystyle xgxg=xg^{2}x}$. Canceling ${\displaystyle xg}$ from the left, we get ${\displaystyle gx=xg}$, which is the goal.

Cube map is automorphism implies abelian (using facts (3) and (4))

Given: A group ${\displaystyle G}$ such that the map sending ${\displaystyle x}$ to ${\displaystyle x^{3}}$ is an automorphism of ${\displaystyle G}$.

To prove: ${\displaystyle G}$ is abelian.

Proof: By fact (2), we conclude that the square map must be an endomorphism of ${\displaystyle G}$. By fact (3), we conclude that therefore ${\displaystyle G}$ must be abelian.

Difference from the corresponding statement for the square map

In the case of the square map, we can in fact prove something much stronger:

${\displaystyle (xy)^{2}=x^{2}y^{2}\iff xy=yx}$

In the case of the cube map, this is no longer true. That is, it may so happen that ${\displaystyle (xy)^{3}=x^{3}y^{3}}$ although ${\displaystyle xy\neq yx}$. Thus, to show that ${\displaystyle xy=yx}$ we need to not only use that ${\displaystyle (xy)^{3}=x^{3}y^{3}}$ but also use that this identity is valid for other elements picked from ${\displaystyle G}$ (specifically, that it is valid for their cuberoots).

References

Textbook references

• Topics in Algebra by I. N. Herstein, ^{More info}, Page 48, Exercise 24

External links

Links to related riders

• Mathlinks discussion forum page for Power maps being homomorphisms implies Abelianness
• Math Stackexchange question on this precise result