Equivalence Class of Fixed Element/Corollary

Theorem
Let $S_n$ denote the symmetric group on $n$ letters.

Let $\sigma \in S_n$.

Let $\mathcal R \paren \sigma$ denote the equivalence defined in Permutation Induces Equivalence Relation.

Let $i \in \N^*_{\le n}$.

Then:
 * $i \notin \Fix \sigma$ $\eqclass i {\mathcal R \paren \sigma}$ contains more than one element

where:
 * $\eqclass i {\mathcal R \paren \sigma}$ denotes the equivalence class of $i$ under $\mathcal R \paren \sigma$
 * $\Fix \sigma$ denotes the set of fixed elements of $\sigma$.

Proof
From Equivalence Class of Fixed Element and Biconditional Equivalent to Biconditional of Negations:
 * $i \notin \Fix \sigma \iff \set i \ne \eqclass i {\mathcal R \paren \sigma}$

Because the Biconditional is Transitive, it suffices to show that:


 * $\set i \ne \eqclass i {\mathcal R \paren \sigma}$


 * $\eqclass i {\mathcal R \paren \sigma}$ contains more than one element.
 * $\eqclass i {\mathcal R \paren \sigma}$ contains more than one element.

Suppose that $\set i \ne \eqclass i {\mathcal R \paren \sigma}$.

From the definition of an equivalence relation it is easily seen that:
 * $\set i \subseteq \eqclass i {\mathcal R \paren \sigma}$

And from the hypothesis:
 * $\set i \subset \eqclass i {\mathcal R \paren \sigma}$

Therefore $\eqclass i {\mathcal R \paren \sigma}$ contains more than one element.

Conversely, if $\eqclass i {\mathcal R \paren \sigma}$ contains more than one element, then it is seen that:
 * $\set i \ne \eqclass i {\mathcal R \paren \sigma}$