Third isomorphism theorem: Difference between revisions

This article gives the statement, and possibly proof, of a basic fact in group theory.
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This article is about an isomorphism theorem in group theory.
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Statement

Suppose ${\displaystyle G}$ is a group, and ${\displaystyle H}$ and ${\displaystyle K}$ are Normal subgroup (?)s of ${\displaystyle G}$, such that ${\displaystyle H\le K}$. Then we have the following natural isomorphism:

${\displaystyle (G/H)/(K/H)\cong G/K}$

Where the isomorphism sends a coset ${\displaystyle Hg}$ in ${\displaystyle G}$ to the coset ${\displaystyle Kg}$ in ${\displaystyle G}$.

Note that this statement makes sense at the level of a group isomorphism only when both ${\displaystyle H}$ and ${\displaystyle K}$ are normal in ${\displaystyle G}$. Otherwise, the statement is still true at the level of sets, but we cannot make sense of it as a group isomorphism.

Related facts

Other isomorphism theorems

• First isomorphism theorem
• Second isomorphism theorem
• Fourth isomorphism theorem (also known as the lattice isomorphism theorem or the correspondence theorem)
• Zassenhaus isomorphism theorem

Facts used

• Normality satisfies intermediate subgroup condition
• Normality is image-closed (not really required; implicitly shown in the proof)
• First isomorphism theorem

Proof

Given: A group ${\displaystyle G}$, with normal subgroups ${\displaystyle H}$ and ${\displaystyle K}$, such that ${\displaystyle H\le K}$

To prove: ${\displaystyle (G/H)/(K/H)\cong G/K}$

Proof: Note first that all the three expressions for quotient groups make sense. ${\displaystyle G/H}$ and ${\displaystyle G/K}$ make sense because ${\displaystyle H,K}$ are normal in ${\displaystyle G}$. Moreover, since normality satisfies intermediate subgroup condition, ${\displaystyle H}$ is also normal in ${\displaystyle K}$.

Next, observe that ${\displaystyle K/H}$ is a normal subgroup in ${\displaystyle G/H}$, because normality is image-closed: under the quotient map by ${\displaystyle H}$, the normal subgroup ${\displaystyle K}$ of ${\displaystyle G}$ gets sent to a normal subgroup ${\displaystyle K/H}$ of ${\displaystyle G/H}$. Thus, the left side makes sense.

Let's now describe the isomorphism from the left side to the right side:

${\displaystyle \psi :G/H\to G/K,\psi (gH)=gK}$

In other words, the map takes a coset of ${\displaystyle H}$ and gives the corresponding coset of ${\displaystyle K}$. This is well-defined, because if ${\displaystyle h\in H}$, then ${\displaystyle h\in K}$, so ${\displaystyle (gh)K=g(hK)=gK}$.

Further, the map is a homomorphism. For this, observe that it sends the identity element to the identity element, preserves the group multiplication, and preserves the inverse map.

Further, the map is surjective, because any coset ${\displaystyle gK}$ occurs as the image of ${\displaystyle gH}$ under ${\displaystyle \psi }$.

Finally, we need to determine the kernel of the map. This is given by the set of ${\displaystyle gH}$ such that ${\displaystyle gK=K}$. This is precisely those cosets of ${\displaystyle H}$ that are in ${\displaystyle K}$, which is the same as the coset space ${\displaystyle K/H}$. Hence, the kernel of the map is precisely ${\displaystyle G/K}$.

Thus, the surjective homomorphism ${\displaystyle \psi :G/H\to G/K}$ has kernel precisely ${\displaystyle K/H}$. By the first isomorphism theorem, we get:

${\displaystyle (G/H)/(K/H)\cong G/K}$.

References

Textbook references

• Abstract Algebra by David S. Dummit and Richard M. Foote, 10-digit ISBN 0471433349, 13-digit ISBN 978-0471433347, ^{More info}, Theorem 19, Section 3,3, Page 98
• Algebra by Michael Artin, ISBN 0130047635, 13-digit ISBN 978-0130047632, ^{More info}, Exercise 8, Miscellaneous Problems, Page 236