Ad­vanced Sem­in­ar "Num­ber The­ory and Arith­met­ic­al Stat­ist­ics"

WiSe 2024/2025

Location: D 2 314                    Time: 14:00 - 15:30

The seminar will take place regularly on wednesdays from October 9th, 2024.

Ober­sem­in­ar "Num­ber The­ory and Arith­met­ic­al Stat­ist­ics": Jan Diek­mann (Duis­burg-Es­sen), Fer­mat's Last The­or­em for reg­u­lar primes

Location: A3.339
Organizer: Prof. Dr. Jürgen Klüners

Titel: Fermat's Last Theorem for regular primes

Abstract:
Definition. For a number field K, let h(K) denote its class number. A prime number p is said to be regular if p ∤ h(Q(ζp)), otherwise irregular.

Theorem. (Fermat’s Last Theorem for regular primes) For a regular prime p ≥ 3, the equation xp + yp = zp does not have a solution in positive integers.

The proof of this theorem is divided into two cases: p ∤ xyz and p | xyz. The latter of these two cases is more complex than the first one. It uses a certain result called Kummer’s Lemma. The proof of Kummer’s Lemma relies on global class field theory.

Theorem. (Kummer’s criterion) Let p be some prime number. Then p | hp if and only if p divides the numerator of some of the Bernoulli numbers Bj
for j = 2, 4, , . . . , p − 3.

The maximal totally real subfield of Q(ζp), Q(ζp)+ = Q(ζp + ζp−1 ) satisfies h(Q(ζp)+) =: h+p | hp := h(Q(ζp)) (proved via global class field theory). We then define hp := hp/h+p . From this point, the proof of Kummer’s criterion consists of the following two theorems:

Theorem. p | hp if and only if p divides the numerator of the Bernoulli number Bj for some j = 2, 4, . . . , p − 3.

Theorem. If p | h+p then p | hp.

The proof of this result relies on global class field theory and on a certain Galois module structure of the p-Sylow subgroups of the ideal class groups of Q(ζp) and Q(ζp)+.

Ober­sem­in­ar "Num­ber The­ory and Arith­met­ic­al Stat­ist­ics": Jan Diek­mann (Duis­burg-Es­sen), Fer­mat's Last The­or­em for reg­u­lar primes

Location: A3.339
Organizer: Prof. Dr. Jürgen Klüners

Titel: Fermat's Last Theorem for regular primes

Abstract:
Definition. For a number field K, let h(K) denote its class number. A prime number p is said to be regular if p ∤ h(Q(ζp)), otherwise irregular.

Theorem. (Fermat’s Last Theorem for regular primes) For a regular prime p ≥ 3, the equation xp + yp = zp does not have a solution in positive integers.

The proof of this theorem is divided into two cases: p ∤ xyz and p | xyz. The latter of these two cases is more complex than the first one. It uses a certain result called Kummer’s Lemma. The proof of Kummer’s Lemma relies on global class field theory.

Theorem. (Kummer’s criterion) Let p be some prime number. Then p | hp if and only if p divides the numerator of some of the Bernoulli numbers Bj
for j = 2, 4, , . . . , p − 3.

The maximal totally real subfield of Q(ζp), Q(ζp)+ = Q(ζp + ζp−1 ) satisfies h(Q(ζp)+) =: h+p | hp := h(Q(ζp)) (proved via global class field theory). We then define hp := hp/h+p . From this point, the proof of Kummer’s criterion consists of the following two theorems:

Theorem. p | hp if and only if p divides the numerator of the Bernoulli number Bj for some j = 2, 4, . . . , p − 3.

Theorem. If p | h+p then p | hp.

The proof of this result relies on global class field theory and on a certain Galois module structure of the p-Sylow subgroups of the ideal class groups of Q(ζp) and Q(ζp)+.

Ober­sem­in­ar "Num­ber The­ory and Arith­met­ic­al Stat­ist­ics": Jan Diek­mann (Duis­burg-Es­sen), Fer­mat's Last The­or­em for reg­u­lar primes

Location: A3.339
Organizer: Prof. Dr. Jürgen Klüners

Titel: Fermat's Last Theorem for regular primes

Abstract:
Definition. For a number field K, let h(K) denote its class number. A prime number p is said to be regular if p ∤ h(Q(ζp)), otherwise irregular.

Theorem. (Fermat’s Last Theorem for regular primes) For a regular prime p ≥ 3, the equation xp + yp = zp does not have a solution in positive integers.

The proof of this theorem is divided into two cases: p ∤ xyz and p | xyz. The latter of these two cases is more complex than the first one. It uses a certain result called Kummer’s Lemma. The proof of Kummer’s Lemma relies on global class field theory.

Theorem. (Kummer’s criterion) Let p be some prime number. Then p | hp if and only if p divides the numerator of some of the Bernoulli numbers Bj
for j = 2, 4, , . . . , p − 3.

The maximal totally real subfield of Q(ζp), Q(ζp)+ = Q(ζp + ζp−1 ) satisfies h(Q(ζp)+) =: h+p | hp := h(Q(ζp)) (proved via global class field theory). We then define hp := hp/h+p . From this point, the proof of Kummer’s criterion consists of the following two theorems:

Theorem. p | hp if and only if p divides the numerator of the Bernoulli number Bj for some j = 2, 4, . . . , p − 3.

Theorem. If p | h+p then p | hp.

The proof of this result relies on global class field theory and on a certain Galois module structure of the p-Sylow subgroups of the ideal class groups of Q(ζp) and Q(ζp)+.