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QUESTION. Are my following conjectures true? How to prove them?

Conjecture 1. For each prime $p>100$, there are $a,b,c\in\{1,\ldots,p-1\}$ such that $$\left(\frac ap\right)=\left(\frac bp\right)=\left(\frac cp\right)=1\ \mbox{and}\ a^2+b^2=c^2,$$ where $(-)$ denotes the Legendre symbol.

Conjecture 2. For each prime $p>50$, there are $a,b,c\in\{1,\ldots,p-1\}$ such that $$\left(\frac ap\right)=\left(\frac bp\right)=\left(\frac cp\right)=-1\ \mbox{and}\ a^2+b^2=c^2.$$

Conjecture 3. For each prime $p>32$, there are $a,b,c\in\{1,\ldots,p-1\}$ such that $$\left(\frac ap\right)=\left(\frac bp\right)=1,\ \left(\frac cp\right)=-1\ \mbox{and}\ a^2+b^2=c^2.$$

Conjecture 4. For each prime $p>72$, there are $a,b,c\in\{1,\ldots,p-1\}$ such that $$\left(\frac ap\right)=\left(\frac bp\right)=-1,\ \left(\frac cp\right)=1\ \mbox{and}\ a^2+b^2=c^2.$$

Remark. I formulated these conjectures in 2015, see http://oeis.org/A260911 . Perhaps, it is practical to prove them.

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  • $\begingroup$ For large primes you can use the circle method. See Corollary 4.15 in Tao and Vu's book on additive combinatorics for an easier variant, which may be modified. $\endgroup$
    – George Shakan
    Commented May 7, 2021 at 11:06
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    $\begingroup$ The circle method does not work in three variables, at least when you have congruences. See the Crelle paper (new version of circle method) of Heath-Brown (comments after Theorem 8). $\endgroup$
    – Dr. Pi
    Commented May 8, 2021 at 15:14
  • $\begingroup$ By Fermat's last theorem, there are no positive squares $a,b,c$ satisfying $a^2+b^2=c^2$. This makes the question particularly interesting. $\endgroup$
    – Zhi-Wei Sun
    Commented May 9, 2021 at 15:22
  • $\begingroup$ I conjecture further that for any prime $p>828$ there is a positive integer $a\le\sqrt{p-2}$ such that $a^2-1,2a,a^2+1$ are all quadratic residues modulo $p$. Note that $(a^2-1)^2+(2a)^2=(a^2+1)^2$. $\endgroup$
    – Zhi-Wei Sun
    Commented May 10, 2021 at 14:58

1 Answer 1

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The Conjecture 1 is true. We are looking for integers $m, n$ such that for sufficiently large prime $p$ we have $$ x_{1}^2\equiv 2mn\pmod{p},\quad x_{2}^2\equiv m^2-n^2\pmod{p}, \quad x_{1}^2\equiv m^2+n^2\pmod{p}. $$ To solve the first congruence we just take $m=2v^2, n=1$, where $v$ need to be specified. With $m, n$ chosen in such way we have $x_{1}=2v$ and we left with the system of congruences $$ (I)\; x_{2}^2\equiv 4v^4-1\pmod{p}, \quad (II)\; x_{3}^2\equiv 4v^4+1\pmod{p}. $$ If we substract the first from the second congruence we get that $x_{3}^2-x_{2}^2\equiv 2\pmod{p}$. To satisfy this congruence we take $$ x_{2}=\frac{1}{2}\left(\frac{1}{t}-2t\right),\quad x_{3}=\frac{1}{2}\left(\frac{1}{t}+2t\right), $$ which comes directly from the parameterization of the affine quadric curve $a^2-b^2=2$. Using the computed values of $x_{2}, x_{3}$ our congruences (I), (II) collapse to the one congruence $$ F(t,v):=4t^4-16v^4t^2+1\equiv 0\pmod{p}. $$ We thus play with the curve $C:\;F(t,v)=0$ over the finite field $\mathbb{F}_{p}$. The genus $g=g_{p}$ of the curve $C$ (depends on $p$) and is bounded by 5. Invoking now the Hasse-Weil bound, i.e., the inequality $$ |\#C(\mathbb{F}_{p})-(p+1)|\leq 2g\sqrt{p}$$ with $g=5$, we obtain that for $p+1-10\sqrt{p}>0$, i.e., for $p>100$ our curve contains a finite point.

Remark 1. One can check that if $p\equiv 1\pmod{4}$ then we can always find effectively a (rather boring) point on $C$ of the form $(t, 0)$, where $t$ is a solution of the congruence $4(4t^4+1)\equiv ((2t+1)^2+1)((2t-1)^2+1)\equiv 0\pmod{p}$. In this case we do not need to invoke Hesse-Weil bound.

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