Let f be a weight 2 newform on Γ₀(qN) – i.e. of level qN where q does not divide N – with absolutely irreducible 2-dimensional mod p Galois representation ρ_f,p unramified at q if q ≠ p and finite flat at q = p. Then there exists a weight 2 newform g of level N such that

${\displaystyle \rho _{f,p}\simeq \rho _{g,p}.}$ 

In particular, if E is an elliptic curve over ${\displaystyle \mathbb {Q} }$  with conductor qN, then the modularity theorem guarantees that there exists a weight 2 newform f of level qN such that the 2-dimensional mod p Galois representation ρ_{f, p} of f is isomorphic to the 2-dimensional mod p Galois representation ρ_{E, p} of E. To apply Ribet's Theorem to ρ_{E, p}, it suffices to check the irreducibility and ramification of ρ_{E, p}. Using the theory of the Tate curve, one can prove that ρ_{E, p} is unramified at q ≠ p and finite flat at q = p if p divides the power to which q appears in the minimal discriminant Δ_E. Then Ribet's theorem implies that there exists a weight 2 newform g of level N such that ρ_{g, p} ≈ ρ_{E, p}.

Ribet's theorem states that beginning with an elliptic curve E of conductor qN does not guarantee the existence of an elliptic curve E′ of level N such that ρ_{E, p} ≈ ρ_{E′, p}. The newform g of level N may not have rational Fourier coefficients, and hence may be associated to a higher-dimensional abelian variety, not an elliptic curve. For example, elliptic curve 4171a1 in the Cremona database given by the equation

${\displaystyle E:y^{2}+xy+y=x^{3}-663204x+206441595}$ 

with conductor 43 × 97 and discriminant 43⁷ × 97³ does not level-lower mod 7 to an elliptic curve of conductor 97. Rather, the mod p Galois representation is isomorphic to the mod p Galois representation of an irrational newform g of level 97.

However, for p large enough compared to the level N of the level-lowered newform, a rational newform (e.g. an elliptic curve) must level-lower to another rational newform (e.g. elliptic curve). In particular for p ≫ N^N1+ε, the mod p Galois representation of a rational newform cannot be isomorphic to an irrational newform of level N.^[2]

Similarly, the Frey-Mazur conjecture predicts that for large enough p (independent of the conductor N), elliptic curves with isomorphic mod p Galois representations are in fact isogenous, and hence have the same conductor. Thus non-trivial level-lowering between rational newforms is not predicted to occur for large p (p > 17).

In his thesis, Yves Hellegouarch [fr] originated the idea of associating solutions (a,b,c) of Fermat's equation with a different mathematical object: an elliptic curve.^[3] If p is an odd prime and a, b, and c are positive integers such that

${\displaystyle a^{p}+b^{p}=c^{p},}$ 

then a corresponding Frey curve is an algebraic curve given by the equation

${\displaystyle y^{2}=x(x-a^{p})(x+b^{p}).}$ 

This is a nonsingular algebraic curve of genus one defined over ${\displaystyle \mathbb {Q} }$ , and its projective completion is an elliptic curve over ${\displaystyle \mathbb {Q} }$ .

In 1982 Gerhard Frey called attention to the unusual properties of the same curve, now called a Frey curve.^[4] This provided a bridge between Fermat and Taniyama by showing that a counterexample to FLT would create a curve that would not be modular. The conjecture attracted considerable interest when Frey suggested that the Taniyama–Shimura–Weil conjecture implies FLT. However, his argument was not complete.^[5] In 1985 Jean-Pierre Serre proposed that a Frey curve could not be modular and provided a partial proof.^[6][7] This showed that a proof of the semistable case of the Taniyama–Shimura conjecture would imply FLT. Serre did not provide a complete proof and the missing bit became known as the epsilon conjecture or ε-conjecture. In the summer of 1986, Kenneth Alan Ribet proved the epsilon conjecture, thereby proving that the Taniyama–Shimura–Weil conjecture implied FLT.^[8]

Suppose that the Fermat equation with exponent p ≥ 5^[8] had a solution in non-zero integers a, b, c. The corresponding Frey curve E_a^p,b^p,c^p is an elliptic curve whose minimal discriminant Δ is equal to 2⁻⁸ (abc)^2p and whose conductor N is the radical of abc, i.e. the product of all distinct primes dividing abc. An elementary consideration of the equation a^p + b^p = c^p, makes it clear that one of a, b, c is even and hence so is N. By the Taniyama–Shimura conjecture, E is a modular elliptic curve. Since all odd primes dividing a, b, c in N appear to a pth power in the minimal discriminant Δ, by Ribet's theorem repetitive level descent modulo p strips all odd primes from the conductor. However, no newforms of level 2 remain because the genus of the modular curve X₀(2) is zero (and newforms of level N are differentials on X₀(N)).

• ABC conjecture
• Wiles' proof of Fermat's Last Theorem

1. ^ . 2008-12-10. Archived from the original on 2008-12-10.
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• Kenneth Ribet, From the Taniyama-Shimura conjecture to Fermat's last theorem. Annales de la faculté des sciences de Toulouse Sér. 5, 11 no. 1 (1990), p. 116–139.
• Andrew Wiles (May 1995). "Modular elliptic curves and Fermat's Last Theorem" (PDF). Annals of Mathematics. 141 (3): 443–551. CiteSeerX 10.1.1.169.9076. doi:10.2307/2118559. JSTOR 2118559.
• Richard Taylor and Andrew Wiles (May 1995). "Ring-theoretic properties of certain Hecke algebras" (PDF). Annals of Mathematics. 141 (3): 553–572. CiteSeerX 10.1.1.128.531. doi:10.2307/2118560. ISSN 0003-486X. JSTOR 2118560. OCLC 37032255. Zbl 0823.11030.
• Frey Curve and Ribet's Theorem

• Ken Ribet and Fermat's Last Theorem by Kevin Buzzard June 28, 2008