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| == Description == |
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| Iwasawa theory for elliptic curves as initiated by Mazur tries to use similar to tools to approach the $p$-adic version of the Birch and Swinnerton-Dyer conjecture. | Iwasawa theory for elliptic curves as initiated by Mazur tries to use similar tools to approach the $p$-adic version of the Birch and Swinnerton-Dyer conjecture. |
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| Let $E/\mathbb{Q}$ be an elliptic curve. Now, we work with an analytic function $L_p(E,s)$ taking values in the $p$-adic numbers. It is built on the values of the complex L-function and can be described explicitly using modular symbols. The conjecture says again that the order of vanishing of $L_p(E,s)$ at $s=1$ is equal to the rank of the Mordell-Weil group $E(\mathbb{Q})$. The big advantage of the $p$-adic setting is that this $p$-adic L-function has a natural link to the arithmetic side via the so called "main conjecture" of Iwasawa theory about which we know quite a lot. |
Let $E/\mathbb{Q}$ be an elliptic curve. The traditional conjecture by Birch and Swinnerton-Dyer states that there is a link between the arithmetic invariance, like the Mordell-Weil group $E(\mathbb{Q})$, and the analytically defined complex L-function. In the $p$-adic BSD, we work with an analytic function $L_p(E,s)$ taking values in the $p$-adic numbers. It is built on the values of the complex L-function and can be described explicitly using modular symbols. The $p$-adic conjecture says again that the order of vanishing of $L_p(E,s)$ at $s=1$ is equal to the rank of the Mordell-Weil group $E(\mathbb{Q})$. (Except in one special case, namely when the curve has split multiplicative reduction at $p$.) The big advantage of the $p$-adic setting is that we actually know something about it. The $p$-adic L-function has a natural link to the arithmetic side via the so called "main conjecture" of Iwasawa theory about which we know quite a lot. Iwasawa theory deals with the question how so the arithmetic objects vary as one climbs up the tower of fields $K_{\infty}/\mathbb{Q}$ obtained by adjoining the $p$-power roots of unity. Similarily one can ask how does the mysterious Tate-Shafarevich group grow (or shrink). Much like the zeta-function for varieties over finite fields, there is a generating function that incodes this information. The main conjecture states that this generating function is equal to the $p$-adic L-function. |
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| A big and difficult theorem by Kato shows that the order of vanishing of $L_p(E,s)$ is at most the rank of $E(\mathbb{Q})$. It even says something about the size of the mysterious Tate-Shafarevich group. Furthermore one can generalize it to abelian extensions $K/Q$. It is suitable for explicit computations. | A big and difficult theorem by Kato shows half of this conjecture and Skinner and Urban claim they have shown the other half of it. As a consequence one gets that the order of vanishing of $L_p(E,s)$ is at most the rank of $E(\mathbb{Q})$. It even says something about the size of the mysterious Tate-Shafarevich group. It also implies that the rank of $E(K_{\infty})$ is finitely generated over the field $K_\infty$. == Projects == The $p$-adic L-function of $E$ can be computed using modular symbols. And sage contains already code to do so. But this code could be improved in several direction. * Allow to twist the function by Dirichlet characters. In particular with the Teichmüllers. * Implement a function that extracts the $\lambda$ and $\mu$ invariant and which decides it the growth of the Selmer group is due to the growth of the Tat-Shafarevich group or due to the increase of the rank. Statistics on the values of these fundamental Iwasawa theoretic invariants. A question I was often asked by Iwasawa theorists is: Are the $\mu$-invariants over $\mathbb{Q}(\zeta_p)$ zero, too. * Can we compute the modular symbols using complex integration ? * Look at overconvergent modular symbols * What happens for primes of additive reduction ? |
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| References | == References == |
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| Mazur, B.; Tate, J.; Teitelbaum, J., On $p$-adic analogues of the conjectures of Birch and Swinnerton-Dyer. Invent. Math. 84 (1986), no. 1, 1--48. [[http://www.ams.org/mathscinet-getitem?mr=830037| math scinet]] |
* Mazur, Tate, Teitelbaum, On $p$-adic analogues of the conjectures of Birch and Swinnerton-Dyer. Invent. Math. 84 (1986), no. 1, 1--48. At [[http://www.ams.org/mathscinet-getitem?mr=830037| mathscinet]] or [[http://gdz.sub.uni-goettingen.de/dms/load/img/?IDDOC=175497|gdz]]. |
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| Stein and Wuthrich, Computations About Tate-Shafarevich Groups Using Iwasawa Theory, preprint http://wstein.org/papers/shark/ . | * Greenberg Ralph, Introduction to Iwasawa Theory for Elliptic Curves, [[http://www.math.washington.edu/~greenber/Park.ps|(paper)]] on [[http://www.math.washington.edu/~greenber/research.html|his web page]] full of Iwasawa theory. Also there is the more advanced Iwasawa Theory for Elliptic Curves [[http://www.math.washington.edu/~greenber/CIME.ps|(paper)]]. * Stein and Wuthrich, Computations About Tate-Shafarevich Groups Using Iwasawa Theory, [[http://wstein.org/papers/shark/|preprint]] . |
Christian Wuthrich (Nottingham): p-adic L-series and Iwasawa theory
Description
Artin and Tate have shown a large part of the conjecture of Birch and Swinnerton-Dyer in the function field case in the 60s. Iwasawa theory for elliptic curves as initiated by Mazur tries to use similar tools to approach the p-adic version of the Birch and Swinnerton-Dyer conjecture.
Let E/\mathbb{Q} be an elliptic curve. The traditional conjecture by Birch and Swinnerton-Dyer states that there is a link between the arithmetic invariance, like the Mordell-Weil group E(\mathbb{Q}), and the analytically defined complex L-function. In the p-adic BSD, we work with an analytic function L_p(E,s) taking values in the p-adic numbers. It is built on the values of the complex L-function and can be described explicitly using modular symbols. The p-adic conjecture says again that the order of vanishing of L_p(E,s) at s=1 is equal to the rank of the Mordell-Weil group E(\mathbb{Q}). (Except in one special case, namely when the curve has split multiplicative reduction at p.)
The big advantage of the p-adic setting is that we actually know something about it. The p-adic L-function has a natural link to the arithmetic side via the so called "main conjecture" of Iwasawa theory about which we know quite a lot. Iwasawa theory deals with the question how so the arithmetic objects vary as one climbs up the tower of fields K_{\infty}/\mathbb{Q} obtained by adjoining the p-power roots of unity. Similarily one can ask how does the mysterious Tate-Shafarevich group grow (or shrink). Much like the zeta-function for varieties over finite fields, there is a generating function that incodes this information. The main conjecture states that this generating function is equal to the p-adic L-function.
A big and difficult theorem by Kato shows half of this conjecture and Skinner and Urban claim they have shown the other half of it. As a consequence one gets that the order of vanishing of L_p(E,s) is at most the rank of E(\mathbb{Q}). It even says something about the size of the mysterious Tate-Shafarevich group. It also implies that the rank of E(K_{\infty}) is finitely generated over the field K_\infty.
Projects
The p-adic L-function of E can be computed using modular symbols. And sage contains already code to do so. But this code could be improved in several direction.
* Allow to twist the function by Dirichlet characters. In particular with the Teichmüllers.
* Implement a function that extracts the \lambda and \mu invariant and which decides it the growth of the Selmer group is due to the growth of the Tat-Shafarevich group or due to the increase of the rank.
Statistics on the values of these fundamental Iwasawa theoretic invariants. A question I was often asked by Iwasawa theorists is: Are the \mu-invariants over \mathbb{Q}(\zeta_p) zero, too.
* Can we compute the modular symbols using complex integration ?
* Look at overconvergent modular symbols
* What happens for primes of additive reduction ?
References
* Mazur, Tate, Teitelbaum, On p-adic analogues of the conjectures of Birch and Swinnerton-Dyer.
Invent. Math. 84 (1986), no. 1, 1--48. At mathscinet or gdz.
* Greenberg Ralph, Introduction to Iwasawa Theory for Elliptic Curves, (paper) on his web page full of Iwasawa theory.
Also there is the more advanced Iwasawa Theory for Elliptic Curves (paper).
* Stein and Wuthrich, Computations About Tate-Shafarevich Groups Using Iwasawa Theory, preprint .