Theorem Suppose that unique factorization holds in \( \mathbb { Z } [ \alpha ] \), and let p be an integer prime such that the polynomial \( P ( x , 1 ) = x ^ { 2 } - b x + c \) has a root mod p. Then there exist integers x and y such that \( P (x, y) = p \). Conversely, if there exist such x and y, then \( x^2 - bx + c \) has a root mod p.
Proof.
- \( \exists x \in \mathbb Z : p \mid x ^ { 2 } - b x + c = (x+\alpha)(x-\alpha) \) but \( p \nmid (x+\alpha)\, \lor \,(x-\alpha) \). So \( p \) is not a prime in \( \mathbb { Z } [ \alpha ] \). \( N(p)=p^2 \implies \exists q = q_1+ q_2 \alpha \in \mathbb { Z } [ \alpha ] : q|p \land N(q)=P(q_1,q_2)=p \)
- Assume \( y \) has an inverse \( y^{-1} \)
mod \( p \). Then
\[ P (x, y)\cdot (y^{-1})^2 \equiv (xy^{-1})^2 -b(xy^{-1}) + c\equiv p \equiv 0 \equiv P ((xy^{-1}), 1) \mod p \]
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Claim 1 y must have an inverse \( y^{-1} \) mod \( p \).
Assume \( y \) does not have an inverse. Since \( p \) is a prime \( y \equiv 0 \mod p \). \( P(x,y)\equiv x^2 \equiv 0 \mod p \implies p|x^2 \implies p^2|x^2 \implies P(x,y)\equiv 0 \mod p^2 \). But \( P(x,y)\equiv p \not\equiv 0 \mod p^2 \)
Contradiction, so \( y \) must have an inverse.
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Lemma 1 Let p be an odd prime. The polynomial \( x^2- bx + c \) has a root mod p if, and only if, \( b^2- 4c \) is zero or a quadratic residue mod p.
Proof.
- \( \exists x \in \mathbb Z : x^2- bx + c \equiv (2x-b)^2+(4c-b^2) \equiv 0 \mod p
\)
\( \implies (2x-b)^2 \equiv b^2- 4c \mod p \)
\( \implies b^2- 4c \) is zero or a quadratic residue mod p
- Since \( p \) is a prime, there exists a primitive root \( r \bmod p \)
\( \implies b^2- 4c \equiv r^{2n} \mod p \)
\[ \text{Set }x=\begin{cases} (r^n+b+p)/2 & \text{if } r^n+b \equiv 1 \bmod 2\\ (r^n+b)/2 & \text{if } r^n+b \equiv 0 \bmod 2 \end{cases} \]\( \implies 2x - b \equiv r^{n} \mod p \)
\( \implies (2x-b)^2+(4c-b^2) \equiv 4 \cdot (x^2- bx + c) \equiv 0 \mod p \)
\( \implies x^2- bx + c \equiv 0 \mod p \)
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