32 research outputs found

    On rational Eisenstein primes and the rational cuspidal groups of modular Jacobian varieties

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    Let NN be a non-squarefree positive integer and let β„“\ell be an odd prime such that β„“2\ell^2 does not divide NN. Consider the Hecke ring T(N)\mathbb{T}(N) of weight 22 for Ξ“0(N)\Gamma_0(N), and its rational Eisenstein primes of T(N)\mathbb{T}(N) containing β„“\ell, defined in Section 3. If m\mathfrak{m} is such a rational Eisenstein prime, then we prove that m\mathfrak{m} is of the form (β„“,Β IM,ND)(\ell, ~\mathcal{I}^D_{M, N}), where the ideal IM,ND\mathcal{I}^D_{M, N} of T(N)\mathbb{T}(N) is also defined in Section 3. Furthermore, we prove that C(N)[m]β‰ 0\mathcal{C}(N)[\mathfrak{m}] \neq 0, where C(N)\mathcal{C}(N) is the rational cuspidal group of J0(N)J_0(N). To do this, we compute the precise order of the cuspidal divisor CM,ND\mathcal{C}^D_{M, N}, defined in Section 4, and the index of IM,ND\mathcal{I}^D_{M, N} in T(N)βŠ—Zβ„“\mathbb{T}(N)\otimes \mathbb{Z}_\ell.Comment: Many arguments are clarified, and many details are filled i

    Rational torsion points on Jacobians of modular curves

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    Let pp be a prime greater than 3. Consider the modular curve X0(3p)X_0(3p) over Q\mathbb{Q} and its Jacobian variety J0(3p)J_0(3p) over Q\mathbb{Q}. Let T(3p)\mathcal{T}(3p) and C(3p)\mathcal{C}(3p) be the group of rational torsion points on J0(3p)J_0(3p) and the cuspidal group of J0(3p)J_0(3p), respectively. We prove that the 33-primary subgroups of T(3p)\mathcal{T}(3p) and C(3p)\mathcal{C}(3p) coincide unless p≑1(mod9)p\equiv 1 \pmod 9 and 3pβˆ’13≑1 ⁣(modp)3^{\frac{p-1}{3}} \equiv 1 \!\pmod {p}

    The rational cuspidal divisor class group of X0(N)X_0(N)

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    For any positive integer NN, we completely determine the structure of the rational cuspidal divisor class group of X0(N)X_0(N), which is conjecturally equal to the rational torsion subgroup of J0(N)J_0(N). More specifically, for a given prime β„“\ell, we construct a rational cuspidal divisor Zβ„“(d)Z_\ell(d) for any non-trivial divisor dd of NN. Also, we compute the order of the linear equivalence class of the divisor Zβ„“(d)Z_\ell(d) and show that the β„“\ell-primary subgroup of the rational cuspidal divisor class group of X0(N)X_0(N) is isomorphic to the direct sum of the cyclic subgroups generated by the linear equivalence classes of the divisors Zβ„“(d)Z_\ell(d).Comment: Comments are welcom

    Abelian arithmetic Chern-Simons theory and arithmetic linking numbers

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    Following the method of Seifert surfaces in knot theory, we define arithmetic linking numbers and height pairings of ideals using arithmetic duality theorems, and compute them in terms of n-th power residue symbols. This formalism leads to a precise arithmetic analogue of a 'path-integral formula' for linking numbers

    Arithmetic Chern-Simons theory II

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    In this paper, we apply ideas of Dijkgraaf and Witten [6, 32] on 3 dimensional topological quantum field theory to arithmetic curves, that is, the spectra of rings of integers in algebraic number fields. In the first three sections, we define classical Chern–Simons actions on spaces of Galois representations. In the subsequent sections, we give formulas for computation in a small class of cases and point towards some arithmetic applications

    NON-OPTIMAL LEVELS OF A REDUCIBLE MOD l MODULAR REPRESENTATION

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    Let l >= 5 be a prime and let N be a square-free integer prime to l. For each prime p dividing N, let ap be either 1 or -1. We give sufficient criteria for the existence of a newform f of weight 2 for G0( N) such that the mod l Galois representation attached to f is reducible and Upf = apf for primes p dividing N. The main techniques used are level raising methods based on an exact sequence due to Ribet. c.2018 American Mathematical Societ
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