Supersingular main conjectures, Sylvester's conjecture and Goldfeld's conjecture

Abstract

We prove a p-converse theorem for elliptic curves E/Q with complex multiplication by the ring of integers OK of an imaginary quadratic field K in which p is ramified. Namely, letting rp = corankZpSelp∞(E/Q), we show that rp 1 rankZE(Q) = ords = 1L(E/Q,s) = rp and \#Sha(E/Q) < ∞. In particular, this has applications to two classical Diophantine problems. First, it resolves Sylvester's conjecture on rational sums of cubes, showing that for all primes 4,7,8 9, there exists (x,y) ∈ Q 2 such that x3 + y3 = . Second, combined with work of Smith, it resolves the congruent number problem in 100\% of cases and establishes Goldfeld's conjecture on ranks of quadratic twists for the congruent number family. The method for showing the above p-converse theorem relies on new interplays between Iwasawa theory for imaginary quadratic fields at nonsplit primes and relative p-adic Hodge theory. In particular, we show that a certain de Rham period qdR can be used to construct anticyclotomic p-adic L-functions for Hecke characters and newforms, interpolating anticyclotomic twists of positive Hodge-Tate weight in the central critical range. Moreover, one can relate the Iwasawa module of elliptic units to these anticyclotomic p-adic L-functions via a new "Coleman map", which is, roughly speaking, the qdR-expansion of the Coleman power series map. Using this, we formulate and prove a new Rubin-type main conjecture for elliptic units, which is eventually related to Heegner points in order to prove the p-converse theorem.