In algebraic geometry, a degeneration (or specialization) is the act of taking a limit of a family of varieties. Precisely, given a morphism
of a variety (or a scheme) to a curve C with origin 0 (e.g., affine or projective line), the fibers
form a family of varieties over C. Then the fiber may be thought of as the limit of as . One then says the family degenerates to the special fiber . The limiting process behaves nicely when is a flat morphism and, in that case, the degeneration is called a flat degeneration. Many authors assume degenerations to be flat.
When the family is trivial away from a special fiber; i.e., is independent of up to (coherent) isomorphisms, is called a general fiber.
Degenerations of curves
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In the study of moduli of curves, the important point is to understand the boundaries of the moduli, which amounts to understand degenerations of curves.
Stability of invariants
Ruled-ness specializes. Precisely, Matsusaka'a theorem says
- Let X be a normal irreducible projective scheme over a discrete valuation ring. If the generic fiber is ruled, then each irreducible component of the special fiber is also ruled.
Infinitesimal deformations
Let D = k be the ring of dual numbers over a field k and Y a scheme of finite type over k. Given a closed subscheme X of Y, by definition, an embedded first-order infinitesimal deformation of X is a closed subscheme X' of Y ×Spec(k) Spec(D) such that the projection X' → Spec D is flat and has X as the special fiber.
If Y = Spec A and X = Spec(A/I) are affine, then an embedded infinitesimal deformation amounts to an ideal I' of A such that A/ I' is flat over D and the image of I' in A = A/ε is I.
In general, given a pointed scheme (S, 0) and a scheme X, a morphism of schemes π: X' → S is called the deformation of a scheme X if it is flat and the fiber of it over the distinguished point 0 of S is X. Thus, the above notion is a special case when S = Spec D and there is some choice of embedding.
See also
- deformation theory
- differential graded Lie algebra
- Kodaira–Spencer map
- Frobenius splitting
- Relative effective Cartier divisor
References
- M. Artin, Lectures on Deformations of Singularities – Tata Institute of Fundamental Research, 1976
- Hartshorne, Robin (1977), Algebraic Geometry, Graduate Texts in Mathematics, vol. 52, New York: Springer-Verlag, ISBN 978-0-387-90244-9, MR 0463157
- E. Sernesi: Deformations of algebraic schemes
- M. Gross, M. Siebert, An invitation to toric degenerations
- M. Kontsevich, Y. Soibelman: Affine structures and non-Archimedean analytic spaces, in: The unity of mathematics (P. Etingof, V. Retakh, I.M. Singer, eds.), 321–385, Progr. Math. 244, Birkh ̈auser 2006.
- Karen E Smith, Vanishing, Singularities And Effective Bounds Via Prime Characteristic Local Algebra.
- V. Alexeev, Ch. Birkenhake, and K. Hulek, Degenerations of Prym varieties, J. Reine Angew. Math. 553 (2002), 73–116.