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Homework 4: Primitive Roots and
Quadratic Reciprocity
DUE WEDNESDAY, OCTOBER 17

William Stein


Date: Math 124 $ \quad$ HARVARD UNIVERSITY $ \quad$ Fall 2001

(1 point) Why do you think that quadratic reciprocity is so cool?

1.
(2 points) Calculate the following symbols by hand: $ \left(\frac{3}{97}\right)$, $ \left(\frac{5}{389}\right)$, $ \left(\frac{2003}{11}\right)$, and $ \left(\frac{5!}{7}\right)$.

2.
(3 points) Prove that $ \displaystyle
\left(\frac{3}{p}\right) =
\begin{cases}\hfill 1 & \text{ if }p\equiv 1, 11\pmod{12},\\
-1 & \text{ if }p\equiv 5, 7\pmod{12}.
\end{cases}$
3.
(3 points) Prove that there is no primitive root modulo $ 2^n$ for any $ n\geq 3$.

4.
(6 points) Prove that if $ p$ is a prime, then there is a primitive root modulo $ p^2$.

5.
(5 points) Use the fact that $ (\mathbb{Z}/p\mathbb{Z})^*$ is cyclic to give a direct proof that $ \left(\frac{-3}{p}\right)=1$ when $ p\equiv 1\pmod{3}$. [Hint: There is an $ c\in (\mathbb{Z}/p\mathbb{Z})^*$ of order $ 3$. Show that $ (2c+1)^2=-3$.]

6.
(6 points) If $ p\equiv 1\pmod{5}$, show directly that $ \left(\frac{5}{p}\right)=1$ by the method of Exercise 5. [Hint: Let $ c\in (\mathbb{Z}/p\mathbb{Z})^*$ be an element of order $ 5$. Show that $ (c+c^4)^2+(c+c^4)-1=0$, etc.]

7.
(4 points) For which primes $ p$ is $ \displaystyle \sum_{a=1}^{p-1} \left(\frac{a}{p}\right)=0$?

8.
(4 points) Artin conjectured that the number of primes $ p\leq x$ such that $ 2$ is a primitive root modulo $ p$ is asymptotic to $ C\pi(x)$ where $ \pi(x)$ is the number of primes $ \leq x$ and $ C$ is a fixed constant called Artin's constant. Using a computer, make an educated guess as to what $ C$ should be, to a few decimal places of accuracy. Explain your reasoning. (Note: Don't try to prove that your guess is correct.)




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William A Stein 2001-12-10