Iwasawa theory of elliptic curves at supersingular primes over ℤ p -extensions of number fields

Abstract: In this paper, we make a study of the Iwasawa theory of an elliptic curve at a supersingular prime p along an arbitrary Zp-extension of a number field K in the case when p splits completely in K. Generalizing work of Kobayashi [8] and Perrin-Riou [16], we define restricted Selmer groups and λ ± , µ ± -invariants; we then derive asymptotic formulas describing the growth of the Selmer group in terms of these invariants. To be able to work with non-cyclotomic Zp-extensions, a new local result is proven that give… Show more

“…Let K ∞ be the cyclotomic Z p -extension of K. We define Sel − p (E/K ∞ ) following [5], [2], and [4]. We will explain this construction in the following sections.…”

“…The construction of plus norm subgroups in [4] does not seem to always work unlike minus norm subgroups. However, when K = Q(µ p ) or p splits completely over K/Q, we have the plus norm subgroups as constructed in [5] and [2], and we can prove the algebraic functional equation for the plus Selmer groups without modifying our technique.…”

The algebraic functional equation of an elliptic curve at supersingular primes

“…Let K ∞ be the cyclotomic Z p -extension of K. We define Sel − p (E/K ∞ ) following [5], [2], and [4]. We will explain this construction in the following sections.…”

“…The construction of plus norm subgroups in [4] does not seem to always work unlike minus norm subgroups. However, when K = Q(µ p ) or p splits completely over K/Q, we have the plus norm subgroups as constructed in [5] and [2], and we can prove the algebraic functional equation for the plus Selmer groups without modifying our technique.…”

The algebraic functional equation of an elliptic curve at supersingular primes

“…But, under the given condition, Proposition 2.3 was proven in [5]. But, under the given condition, Proposition 2.3 was proven in [5].…”

The Plus/Minus Selmer Groups for Supersingular Primes

“…The trace relations between the c n then yield relations between the P n by diagrams (5) and (6). We have n+1/n (P n+1 ) = a p P n − n−1/n (P n−1 ),…”

An algebraic version of a theorem of Kurihara