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Taniyama's problems are a set of 36 mathematical problems posed by Japanese mathematician Yutaka Taniyama in 1955. The problems primarily focused on algebraic geometry, number theory, and the connections between modular forms and elliptic curves.

History

In the 1950s post-World War II period of mathematics, there was renewed interest in the theory of modular curves due to the work of Taniyama and Goro Shimura. During the 1955 international symposium on algebraic number theory at Tokyo and Nikkō—the first symposium of its kind to be held in Japan that was attended by international mathematicians including Jean-Pierre Serre, Emil Artin, Andre Weil, Richard Brauer, K. G. Ramanathan, and Daniel Zelinsky—Taniyama compiled his 36 problems in a document titled "Problems of Number Theory" and distributed mimeographs of his collection to the symposium's participants. These problems would become well known in mathematical folklore. Serre later brought attention to these problems in the early 1970s.

The most famous of Taniyama's problems are his twelfth and thirteenth problems. These problems led to the formulation of the Taniyama–Shimura conjecture (now known as the modularity theorem), which states that every elliptic curve over the rational numbers is modular. This conjecture became central to modern number theory and played a crucial role in Andrew Wiles' proof of Fermat's Last Theorem in 1995.

Taniyama's problems influenced the development of modern number theory and algebraic geometry, including the Langlands program, the theory of modular forms, and the study of elliptic curves.

The problems

Taniyama's tenth problem addressed Dedekind zeta functions and Hecke L-series, and while distributed in English at the 1955 Tokyo-Nikkō conference attended by both Serre and André Weil, it was only formally published in Japanese in Taniyama's collected works.

Let ${\displaystyle k}$ be a totally real number field, and ${\displaystyle F(\tau )}$ be a Hilbert modular form to the field ${\displaystyle k}$. Then, choosing ${\displaystyle F(\tau )}$ in a suitable manner, we can obtain a system of Erich Hecke's L-series with Größencharakter ${\displaystyle \lambda }$, which corresponds one-to-one to this ${\displaystyle F(\tau )}$ by the process of Mellin transformation. This can be proved by a generalization of the theory of operator ${\displaystyle T}$ of Hecke to Hilbert modular functions (cf. Hermann Weyl).

According to Serge Lang, Taniyama's eleventh problem deals with elliptic curves with complex multiplication, but is unrelated to Taniyama's twelfth and thirteenth problems.

Let ${\displaystyle C}$ be an elliptic curve defined over an algebraic number field ${\displaystyle k}$, and ${\displaystyle L_{C}(s)}$ the L-function of ${\displaystyle C}$ over ${\displaystyle k}$ in the sense that ${\displaystyle \zeta _{C}(s)=\zeta _{k}(s)\zeta _{k}(s-1)/L_{C}(s)}$ is the zeta function of ${\displaystyle C}$ over ${\displaystyle k}$. If the Hasse–Weil conjecture is true for ${\displaystyle \zeta _{C}(s)}$, then the Fourier series obtained from ${\displaystyle L_{C}(s)}$ by the inverse Mellin transformation must be an automorphic form of dimension -2 of a special type (see Hecke). If so, it is very plausible that this form is an ellipic differential of the field of associated automorphic functions. Now, going through these observations backward, is it possible to prove the Hasse-Weil conjecture by finding a suitable automorphic form from which ${\displaystyle L_{C}(s)}$ can be obtained?

Taniyama's twelfth problem's significance lies in its suggestion of a deep connection between elliptic curves and modular forms. While Taniyama's original formulation was somewhat imprecise, it captured a profound insight that would later be refined into the modularity theorem. The problem specifically proposed that the L-functions of elliptic curves could be identified with those of certain modular forms, a connection that seemed surprising at the time.

Fellow Japanese mathematician Goro Shimura noted that Taniyama's formulation in his twelfth problem was unclear: the proposed Mellin transform method would only work for elliptic curves over rational numbers. For curves over number fields, the situation is substantially more complex and remains unclear even at a conjectural level today.

To characterize the field of elliptic modular functions of level ${\displaystyle N}$, and especially to decompose the Jacobian variety ${\displaystyle J}$ of this function field into simple factors up to isogeny. Also it is well known that if ${\displaystyle N=q}$, a prime, and ${\displaystyle q\equiv 3{\pmod {4}}}$, then ${\displaystyle J}$ contains elliptic curves with complex multiplication. What can one say for general ${\displaystyle N}$?

See also

• Hilbert's problems
• Thurston's 24 questions
• List of unsolved problems in mathematics
• Wiles's proof of Fermat's Last Theorem

Notes

1. The reference to Hecke in Problem 12 was to his paper, "fiber die Bestimmung Dirichletscher Reihen durch ihre Funktionalgleichung", which involves not only congruence subgroups of ${\displaystyle {\text{SL}}_{2}(\mathbb {Z} )}$ but also some Fuchsian groups not commensurable with it.

References

1. ^ Shimura, Goro (1989), "Yutaka Taniyama and his time. Very personal recollections", The Bulletin of the London Mathematical Society, 21 (2): 186–196, doi:10.1112/blms/21.2.186, ISSN 0024-6093, MR 0976064
2. ^ Mazur, B. (1991), "Number Theory as Gadfly", The American Mathematical Monthly, 98 (7): 593–610
3. ^ Lang, Serge (1995), "Some History of the Shimura-Taniyama Conjecture", Notices of the AMS, 42 (11): 1301–1307
4. Proceedings of the International Symposium on Algebraic Number Theory, The Organizing Committee International Symposium on Algebraic Number Theory, 1955
5. ^ "Taniyama-Shimura Conjecture". Wolfram MathWorld. Retrieved December 27, 2024.
6. Taniyama, Yutaka (1956), "Problem 12", Sugaku (in Japanese), 7: 269

• Number theory
• Algebraic geometry
• Mathematical problems