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  1. Let E / Q E/\mathbf {Q} be an elliptic curve and let p p be an odd prime of good reduction for E E . Let K K be an imaginary quadratic field satisfying the classical Heegner hypothesis and in which p p splits. The goal of this paper is two-fold: (1) we formulate a p p -adic BSD conjecture for the p p -adic L L -function L p B D P L_\mathfrak {p}^{\mathrm {BDP}} introduced by Bertolini–Darmon–Prasanna [Duke Math. J. 162 (2013), pp. 1033–1148]; and (2) for an algebraic analogue F p ÂŻ<#comment/> B D P F_{\overline {\mathfrak {p}}}^{\mathrm {BDP}} of L p B D P L_\mathfrak {p}^{\mathrm {BDP}} , we show that the “leading coefficient” part of our conjecture holds, and that the “order of vanishing” part follows from the expected “maximal non-degeneracy” of an anticyclotomic p p -adic height. In particular, when the Iwasawa–Greenberg Main Conjecture ( F p ÂŻ<#comment/> B D P ) = ( L p B D P ) (F_{\overline {\mathfrak {p}}}^{\mathrm {BDP}})=(L_\mathfrak {p}^{\mathrm {BDP}}) is known, our results determine the leading coefficient of L p B D P L_{\mathfrak {p}}^{\mathrm {BDP}} at T = 0 T=0 up to a p p -adic unit. Moreover, by adapting the approach of Burungale–Castella–Kim [Algebra Number Theory 15 (2021), pp. 1627–1653], we prove the main conjecture for supersingular primes p p under mild hypotheses. In the p p -ordinary case, and under some additional hypotheses, similar results were obtained by Agboola–Castella [J. ThĂ©or. Nombres Bordeaux 33 (2021), pp 629–658], but our method is new and completely independent from theirs, and apply to all good primes. 
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  2. Abstract Let $$E/\mathbf {Q}$$ be an elliptic curve and $p>3$ be a good ordinary prime for E and assume that $L(E,1)=0$ with root number $+1$ (so $$\text {ord}_{s=1}L(E,s)\geqslant 2$$ ). A construction of Darmon–Rotger attaches to E and an auxiliary weight 1 cuspidal eigenform g such that $$L(E,\text {ad}^{0}(g),1)\neq 0$$ , a Selmer class $$\kappa _{p}\in \text {Sel}(\mathbf {Q},V_{p}E)$$ , and they conjectured the equivalence $$ \begin{align*} \kappa_{p}\neq 0\quad\Longleftrightarrow\quad{\textrm{dim}}_{{\mathbf{Q}}_{p}}\textrm{Sel}(\mathbf{Q},V_{p}E)=2. \end{align*} $$ In this article, we prove the first cases on Darmon–Rotger’s conjecture when the auxiliary eigenform g has complex multiplication. In particular, this provides a new construction of nontrivial Selmer classes for elliptic curves of rank 2. 
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  3. Abstract In this paper, we prove one divisibility of the Iwasawa–Greenberg main conjecture for the Rankin–Selberg product of a weight two cusp form and an ordinary complex multiplication form of higher weight, using congruences between Klingen Eisenstein series and cusp forms on $$\mathrm {GU}(3,1)$$ , generalizing an earlier result of the third-named author to allow nonordinary cusp forms. The main result is a key input in the third-named author’s proof of Kobayashi’s $$\pm $$ -main conjecture for supersingular elliptic curves. The new ingredient here is developing a semiordinary Hida theory along an appropriate smaller weight space and a study of the semiordinary Eisenstein family. 
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