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Semistable reduction theorem

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In algebraic geometry, semistable reduction theorems state that, given a proper flat morphism , there exists a morphism (called base change) such that is semistable (i.e., the singularities are mild in some sense). Precise formulations depend on the specific versions of the theorem. For example, if is the unit disk in , then "semistable" means that the special fiber is a divisor with normal crossings.[1]

The fundamental semistable reduction theorem for Abelian varieties by Grothendieck shows that if is an Abelian variety over the fraction field of a discrete valuation ring , then there is a finite field extension such that has semistable reduction over the integral closure of in . Semistability here means more precisely that if is the Néron model of over then the fibres of over the closed points (which are always a smooth algebraic groups) are extensions of Abelian varieties by tori.[2] Here is the algebro-geometric analogue of "small" disc around the , and the condition of the theorem states essentially that can be thought of as a smooth family of Abelian varieties away from ; the conclusion then shows that after base change this "family" extends to the so that also the fibres over the are close to being Abelian varieties.

The important semistable reduction theorem for algebraic curves was first proved by Deligne and Mumford.[3] The proof proceeds by showing that the curve has semistable reduction if and only if its Jacobian variety (which is an Abelian variety) has semistable reduction; one then applies the theorem for Abelian varieties above.

References

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  1. ^ Morrison 1984, § 1.
  2. ^ Grothendieck (1972), Théorème 3.6, p. 351
  3. ^ Deligne & Mumford 1969, Corollary 2.7.
  • Deligne, P.; Mumford, D. (1969). "The irreducibility of the space of curves of given genus". Publications Mathématiques de l'Institut des Hautes Scientifiques. 36 (36): 75–109. doi:10.1007/BF02684599. S2CID 16482150.
  • Grothendieck, Alexandre (1972). Groupes de Monodromie en Géométrie Algébrique. Lecture Notes in Mathematics (in French). Vol. 288. Berlin; New York: Springer-Verlag. viii+523. doi:10.1007/BFb0068688. ISBN 978-3-540-05987-5. MR 0354656.
  • Kempf, G.; Knudsen, Finn Faye; Mumford, David; Saint-Donat, B. (1973), Toroidal Embeddings I, Lecture Notes in Mathematics, vol. 339, Berlin, New York: Springer-Verlag, doi:10.1007/BFb0070318, ISBN 978-3-540-06432-9, MR 0335518
  • Morrison, David R. (1984). "Chapter VI. The Clemens-Schmid exact sequence and applications" (PDF). Topics in Transcendental Algebraic Geometry. (AM-106). pp. 101–120. doi:10.1515/9781400881659-007. ISBN 9781400881659. S2CID 125739605.

Further reading

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