Plan of the course Analytic and Cobinatorial Number Theory in summer term 2025/26

Finite fields and their combimatorial applications

Counting solutions of diagonal congruences mod p

An elementary proof of Weil's theorem on numbers of solutions of polynomial congruences mod p

lecture notes (preliminary, updated March 23, 2026)

Lecture 1, February 16, 2026 Finite fields

Lecture 2, February 23, 2026 Sidon sets

Lecture 3, March 2, 2026 Combinatorial applications of the Chevalley - Warning theorem

Lecture 4, March 9, 2026 A theorem from Borevich and Shafarevich on the number of solutions of a_1x^{r_1}+... +a_nx^{r_n} = 0 in F = Z_p (without proof). Beginning of the proof of Theorem 1: If N is the # of solutions of P(X, Y)=0 in Z_p, where P(X, Y) is abs. irreducible with d = deg(P) such that p > 250d^5, then |N - p|<(2d^5*p)^{1/2}.

Lecture 5, March 16, 2026 Continuation 1 of the proof of Theorem 1: If N is the # of solutions of P(X, Y)=0 in Z_p, where P(X, Y) is abs. irreducible with d = deg(P) such that p > 250d^5, then |N - p|<(2d^5*p)^{1/2}.

Lecture 6, March 23, 2026 Continuation 2 of the proof of Theorem 1: If N is the # of solutions of P(X, Y)=0 in Z_p, where P(X, Y) is abs. irreducible with d = deg(P) such that p > 250d^5, then |N - p|<(2d^5*p)^{1/2}.

Lecture 7, March 30, 2026 I planned to lecture on the Dirichlet theorem on primes in AP but nobody came.

April 6, 2026 no lecture - Easter Monday