The symmetric group Sn is not abelian for n ≥ 3. In other words, there are elements of Sn that do not commute each other. In this page, we will prove that the symmetric group Sn is not commutative. Before that let us recall abelian group.
A group (G, ∗) is called an abelian group if a∗b = b∗a ∀ a,b ∈ G, that is, the elements of G commute each other.
Table of Contents
Symmetric Group is not Abelian Proof
Let us prove that the symmetric group Sn is not abelian whenever n≥3.
Proof:
Since n≥3, let us consider two permutations σ= $\left( {\begin{array}{*{20}{c}}1&2&3 \\ 3&2&1 \end{array}} \right)$ and τ = $\left( {\begin{array}{*{20}{c}}1&2&3 \\ 1&3&2 \end{array}} \right)$ on {1, 2, 3, …, n}.
Now στ = $\left( {\begin{array}{*{20}{c}}1&2&3 \\ 3&1&2 \end{array}} \right)$
τσ = $\left( {\begin{array}{*{20}{c}}1&2&3 \\ 2&3&1 \end{array}} \right)$
Hence, στ ≠ τσ.
That is, σ and τ do not commute each other. This proves that the symmetric group Sn is not abelian provided that n≥3.
Read Also: Order of a Permutation in a Symmetric Group
Remark: If G is an abelian group, then its center Z(G) = G. But, the center of the symmetric group Sn is trivial for n ≥ 3. Thus, Sn is not abelian for n ≥ 3.
Related Topics:
- Basics of Group Theory
- Group of order 4 is abelian: Proof
- Cyclic Group
- Group of prime order is cyclic
- Normal Subgroup
- Quotient Group
- Homomorphism of Groups
- First Isomorphism Theorem
FAQs
Answer: We know that the center of Sn is trivial. If the symmetric group is abelian then its center would have been non-trivial. This makes Sn non-abelian.
Answer: No, S3 is not abelian. This is because (1 2) (2 3) ≠ (2 3) (1 2).
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