Arithmetic Aspects of Weil Bundles over p-Adic Manifolds
Abstract
We introduce a systematic theory of Weil bundles over \( p \)-adic analytic manifolds, forging new connections between differential calculus over non-archimedean fields and arithmetic geometry. By developing a framework for infinitesimal structures in the \( p \)-adic setting, we establish that Weil bundles \( MA \) associated with a \( p \)-adic manifold \( M \) and a Weil algebra \( A \) inherit a canonical analytic structure. Key results include: Lifting theorems : for analytic functions, vector fields, and connections, enabling the transfer of geometric data from \( M \) to \( MA \). A Galois-equivariant structure : on Weil bundles defined over number fields, linking their geometry to arithmetic symmetries. A cohomological comparison isomorphism: between the Weil bundle \( MA \) and the crystalline cohomology of \( M \), unifying infinitesimal and crystalline perspectives. Applications to Diophantine geometry and \( p \)-adic Hodge theory are central to this work. We show that spaces of sections of Hodge bundles on \( MA \) parametrize \( p \)-adic modular forms, offering a geometric interpretation of deformation-theoretic objects. Furthermore, Weil bundles are used to study infinitesimal solutions of equations on elliptic curves, revealing new structural insights into \( p \)-adic deformations.
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