Sunday, 9 September 2018

Catalan's Conjecture - A learning exercise for the bored mind - Contd.

Before we move to Mihailescu’s proof, let us cover some more mathematical concepts (so that we feel superior to the people around us, just kidding :smile:),

There is an interesting theorem that Mihailescu uses in his proof, called the Stickelberger’s theorem,


Stickelberger’s theorem:

This is a result of algebraic number theory, which gives more information about Galois Module structure of class groups of Cyclotomic Fields.
This theorem consists of Stickelberger’s element and Stickelberger’s ideal.
I will now state the complete definition of the theorem and then visit its corners as we move along,

Let denote the -th cyclotomic field . It is a Galois extension of with Galois Group isomorphic to the multiplicative group of integers modulo .

The Stickelberger element (of level or of ) is an element in thr group ring and the Stickelberger ideal is an ideal in the group ring . (Note: ).

The definition of both the Stickelberger element and ideal are, let denote a primitive -th root of unity . The isomorphism from to is given by sending to by the relation
The Stickelberger element of level is given by,

The Stickelberger ideal of level is given by,


Inkeri, used the concept of Wiefrich pair (explain in the previous blogpost of this series) in the context of Catalan’s equation as follows:

A Wieferich pair is a pair of primes such that and

He showed that if the Catalan’s equation holds, then either is a Wieferich pair, or divides , the class number of cyclotomic field , or divides , the class number of cyclotomic field , there were other developments in this direction too.

Bugeaud and Hanrot proved a class number criterion concerning Catalan’s equation, which implies that the Catalan’s Equation ( ) has no solutions in non-zero integers and if and are primes such that one of them is smaller than 43. This was a huge achievement , I recommend you to have a look at the paper at [5].

Mihailescu proved that the Catalan equation has no solutions if and are odd and does not divide . By this result the Catalan conjecture became a theorem. And later Mihailescu succeeded in finding a more elegant proof of Catalan’s conjecture in the case where does divide . Thus, Catalan’s conjecture is a theorem with an algebraic proof in which no computer calculations
are needed.



In this section e wll discuss some breakthrough results by Mihailescu. The most important one is that divides .

The following lemma will be used for that, an element of a ring is called nilpotent if and integer such that .

Lemma 1: The ring does not contain nilpotent elements, if , satisfy the congruence

Theorem 1: For , the element is a in . We also have that divides and divides .

The proofs of the above Lemma and Theorem are beyond the scope of this blog; regardless to say that the pre-requisites are already covered in detail. For the interested, you can refer Catalan’s Conjecture - A cyclotomic field.

Cheers!