Normality satisfies transfer condition

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Statement

Verbal statement

If a subgroup is normal in the group, its intersection with any other subgroup is normal in that subgroup.

Symbolic statement

Let $H \leq G$ be a normal subgroup and let $K$ be any subgroup of $G$ . Then, $H \cap K ◃ K$ .

Property-theoretic statement

The subgroup property of being normal satisfies the transfer condition.

Definitions used

Normal subgroup

A subgroup $H$ of a group $G$ is said to be normal if for any $g \in G$ and $h \in H$ , $g h g^{- 1} \in H$ .

Transfer condition

A subgroup property $p$ is said to satisfy transfer condition if whenever $H, K$ are subgroups of $G$ and $H$ has property $p$ in $G$ , $H \cap K$ has property $p$ in $K$ .

Related facts

Further facts

Second isomorphism theorem: This result equates the quotient of the non-normal subgroup, by the intersection, with the quotient of the product of subgroups, by the normal subgroup. Specifically, it states that if $H$ is normal in $G$ and $K$ is any subgroup of $G$ , we have $H / (H \cap K) ≅ H K / K$ .

Related metaproperties satisfied by normality

Normality satisfies intermediate subgroup condition: The intermediate subgroup condition is weaker. It says that if $H \leq K \leq G$ are subgroups are $H$ is normal in $G$ , then $H$ is normal in $K$ .
Normality satisfies inverse image condition: The inverse image condition is stronger. It says that the inverse image of a normal subgroup under a homomorphism is normal.

Other metaproperties satisfied by normality, that are somewhat related:

Normality satisfies image condition: The image of a normal subgroup under a surjective homomorphism is normal in the image.
Normality is upper join-closed

Transfer condition for other subgroup properties

Subnormality satisfies transfer condition: This follows directly from the fact that normality satisfies the transfer condition, and the fact that transfer condition is subordination-closed.
Permutability satisfies transfer condition

Analogues in other algebraic structure

Ideal property satisfies transfer condition in Lie rings

Proof

Hands-on proof

Given: A group $G$ , a normal subgroup $H ◃ G$ and a subgroup $K \leq G$

To prove: $H \cap K ◃ K$ . In other words, we need to prove that given any $g \in K$ and $h \in H \cap K$ , $g h g^{- 1} \in H \cap K$ .

Proof: Since $h \in H \cap K$ , we in particular have $h \in H$ . Since $H ◃ G$ (viz $H$ is normal in $G$ ), $g h g^{- 1} \in H$ .

But we also have that $g \in K$ and $h \in K$ . Since $K$ is a subgroup, $g h g^{- 1} \in K$ .

Combining these two facts, $g h g^{- 1} \in H \cap K$ .

References

Textbook references

Abstract Algebra by David S. Dummit and Richard M. Foote, 10-digit ISBN 0471433349, 13-digit ISBN 978-0471433347, ^{More info}, Page 88, Exercise 24
Topics in Algebra by I. N. Herstein, ^{More info}, Page 53, Problem 5