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Repr{\'e}sentations p-adiques et {\'e}quations diff{\'e}rentielles

数论 2009-11-07 v3 交换代数 代数几何

摘要

In this paper, we associate to every pp-adic representation VV a pp-adic differential equation Drig(V)\mathbf{D}^{\dagger}_{\mathrm{rig}}(V), that is to say a module with a connection over the Robba ring. We do this via the theory of Fontaine's (ϕ,ΓK)(\phi,\Gamma_K)-modules. This construction enables us to relate the theory of (ϕ,ΓK)(\phi,\Gamma_K)-modules to pp-adic Hodge theory. We explain how to construct mathbfDmathrmcris(V)mathbf{D}_{mathrm{cris}}(V) and Dst(V)\mathbf{D}_{\mathrm{st}}(V) from Drig(V)\mathbf{D}^{\dagger}_{\mathrm{rig}}(V), which allows us to recognize semi-stable or crystalline representations; the connection is then either unipotent or trivial on Drig(V)[1/t]\mathbf{D}^{\dagger}_{\mathrm{rig}}(V)[1/t]. In general, the connection has an infinite number of regular singularities, but we show that VV is de Rham if and only if those are apparent singularities. A structure theorem for modules over the Robba ring allows us to get rid of all singularities at once, and to obtain a ``classical'' differential equation, with a Frobenius structure. A recent theorem of Y. Andr\'e gives a complete description of the structure of such an object. This allows us to prove Fontaine's pp-adic monodromy conjecture: every de Rham representation is potentially semi-stable. As an application, we can extend to the case of arbitrary perfect residue fields some results of Hyodo (Hg1=Hst1H^1_g=H^1_{st}), of Perrin-Riou (the semi-stability of ordinary representations), of Colmez (absolutely crystalline representations are of finite height), and of Bloch and Kato (if the weights of VV are 2\geq 2, then Bloch-Kato's exponential expV\exp_V is an isomorphism).

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引用

@article{arxiv.math/0102179,
  title  = {Repr{\'e}sentations p-adiques et {\'e}quations diff{\'e}rentielles},
  author = {Laurent Berger},
  journal= {arXiv preprint arXiv:math/0102179},
  year   = {2009}
}

备注

71 pages. In French. Uses Xypic. 3rd Version: this revised version includes a proof of Fontaine's monodromy conjecture and some applications. Submitted for publication