Euler's Criterion

Euler’s Criterion Let p be an odd prime, and a an integer not divisible by p. Then

\[ (\frac{a}{p}) \equiv a^{\frac{p-1}{2}}\mod p \]
Proof.
  1. \( (\frac{a}{p})=1 \), i.e. \( \exists d : d^2 \equiv a \mod p \)
    \[ \implies a^{\frac{p-1}{2}} \equiv d^{p-1} \equiv 1 \equiv (\frac{a}{p}) \mod p \]
  2. \( (\frac{a}{p})=-1 \), i.e. \( \forall d : d^2 \not\equiv a \mod p \) since p is a prime, \( \exists g \in (\mathbb Z/p\mathbb Z)^\times:(\mathbb Z/p\mathbb Z)^\times= <g>\implies a=g^{2n+1} \)
    \[ \implies a^{\frac{p-1}{2}} \equiv g^{\frac{(2n+1)(p-1)}{2}}\equiv g^{n(p-1)+\frac{p-1}{2}} \equiv g^\frac{p-1}{2} \mod p \]

    since p is a prime

    \begin{align*} &\implies (g^\frac{p-1}{2})^2 \equiv 1 \mod p \\ &\implies g^\frac{p-1}{2}\equiv1 \mod p \lor g^\frac{p-1}{2}\equiv-1 \mod p \end{align*}

    since g is a generator

    \begin{align*} &\implies g^\frac{p-1}{2}\not\equiv1 \mod p\\ &\implies g^\frac{p-1}{2} \equiv -1 \equiv (\frac{a}{p}) \mod p \end{align*}

Therefore, this theorem is true.

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