Faltings's theorem is a result in arithmetic geometry, according to which a curve of genus greater than 1 over the field

This was conjectured in 1922 by Louis Mordell,[1] and known as the Mordell conjecture until its 1983 proof by Gerd Faltings.

be a non-singular algebraic curve of genus

Then the set of rational points on

may be determined as follows: Igor Shafarevich conjectured that there are only finitely many isomorphism classes of abelian varieties of fixed dimension and fixed polarization degree over a fixed number field with good reduction outside a fixed finite set of places.

[3] Aleksei Parshin showed that Shafarevich's finiteness conjecture would imply the Mordell conjecture, using what is now called Parshin's trick.

[4] Gerd Faltings proved Shafarevich's finiteness conjecture using a known reduction to a case of the Tate conjecture, together with tools from algebraic geometry, including the theory of Néron models.

[5] The main idea of Faltings's proof is the comparison of Faltings heights and naive heights via Siegel modular varieties.

[a] Faltings's 1983 paper had as consequences a number of statements which had previously been conjectured: A sample application of Faltings's theorem is to a weak form of Fermat's Last Theorem: for any fixed

by an arbitrary finite-rank subgroup of

leads to the Mordell–Lang conjecture, which was proved in 1995 by McQuillan[9] following work of Laurent, Raynaud, Hindry, Vojta, and Faltings.

Another higher-dimensional generalization of Faltings's theorem is the Bombieri–Lang conjecture that if

Even more general conjectures have been put forth by Paul Vojta.

The Mordell conjecture for function fields was proved by Yuri Ivanovich Manin[10] and by Hans Grauert.

[11] In 1990, Robert F. Coleman found and fixed a gap in Manin's proof.