Fermat–Catalan conjecture

In number theory, the Fermat–Catalan conjecture combines ideas of Fermat's last theorem and the Catalan conjecture, hence the name. The conjecture states that the equation

$a^{m}+b^{n}=c^{k}\quad$

(1)

has only finitely many solutions (a,b,c,m,n,k) with distinct triplets of values (a^m, bⁿ, c^k); here a, b, c are positive coprime integers and m, n, k are positive integers satisfying

${\frac {1}{m}}+{\frac {1}{n}}+{\frac {1}{k}}<1.$

(2)

This inequality restriction on the exponents has the effect of precluding consideration of the known infinitude of solutions of (1) in which two of the exponents are 2 (such as Pythagorean triples).

As of 2015, the following ten solutions to (1) are known:^[1]

1^{m}+2^{3}=3^{2}\;

2^{5}+7^{2}=3^{4}\;

13^{2}+7^{3}=2^{9}\;

2^{7}+17^{3}=71^{2}\;

3^{5}+11^{4}=122^{2}\;

33^{8}+1549034^{2}=15613^{3}\;

1414^{3}+2213459^{2}=65^{7}\;

9262^{3}+15312283^{2}=113^{7}\;

17^{7}+76271^{3}=21063928^{2}\;

43^{8}+96222^{3}=30042907^{2}\;

The first of these (1^m+2³=3²) is the only solution where one of a, b or c is 1, according to the Catalan conjecture, proven in 2002 by Preda Mihăilescu. While this case leads to infinitely many solutions of (1) (since we can pick any m for m>6), these solutions only give a single triplet of values (a^m, bⁿ, c^k).

It is known by the Darmon–Granville theorem, which uses Faltings' theorem, that for any fixed choice of positive integers m, n and k satisfying (2), only finitely many coprime triples (a, b, c) solving (1) exist;^[2]^[3]^{:p. 64} but the full Fermat–Catalan conjecture is a much stronger statement since it allows for an infinitude of sets of exponents m, n and k.

The abc conjecture implies the Fermat–Catalan conjecture.^[1]

Beal's conjecture is true if and only if all Fermat-Catalan solutions use 2 as an exponent for some variable.

References

1 2 Pomerance, Carl (2008), "Computational Number Theory", in Gowers, Timothy; Barrow-Green, June; Leader, Imre, The Princeton Companion to Mathematics, Princeton University Press, pp. 361–362, ISBN 978-0-691-11880-2 .
↑ Darmon, H.; Granville, A. (1995). "On the equations z^m = F(x, y) and Ax^p + By^q = Cz^r". Bulletin of the London Mathematical Society. 27: 513–43.
↑ Elkies, Noam D. (2007). "The ABC's of Number Theory" (PDF). The Harvard College Mathematics Review. 1 (1).

External links

Perfect Powers: Pillai's works and their developments. Waldschmidt, M.

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Fermat–Catalan conjecture

See also

References

External links