Moduli scheme: Difference between revisions

Work of Grothendieck and [[David Mumford]] (see [[geometric invariant theory]]) opened up this area in the early 1960s. The more algebraic and abstract approach to moduli problems is to set them up as a [[representable functor]] question, then apply a criterion that singles out the representable [[functor]]s for schemes. When this programmatic approach works, the result is a ''fine moduli scheme''. Under the influence of more geometric ideas, it suffices to find a scheme that gives the correct [[geometric point]]s. This is more like the classical idea that the moduli problem is to express the [[algebraic structure]] naturally coming with a set (say of isomorphism classes of [[elliptic curve]]s).

Mumford proved that if ''g'' > 1, there exists a coarse moduli scheme of smooth curves of genus ''g'', which is [[quasi-projective]].<ref>{{cite book |chapter=10.4 Coarse moduli schemes |chapter-url=https://books.google.com/books?id=ByTyBwAAQBAJ&pg=PA83|title=Resolution of Singularities: A research textbook in tribute to Oscar Zariski Based on the courses given at the Working Week in Obergurgl, Austria, September 7–14, 1997|last1=Hauser|first1=Herwig|last2=Lipman|first2=Joseph|last3=Oort|first3=Frans|last4=Quirós|first4=Adolfo|date=2012-12-06|publisher=Birkhäuser|isbn=9783034883993|page=83|access-date=22 August 2017}}</ref> According to a recent survey by [[János Kollár]], it "has a rich and intriguing intrinsic geometry which is related to major questions in many branches of mathematics and [[theoretical physics]]."<ref>{{cite book |first=János |last=Kollár |chapter=1.1. Short History Of Moduli Problems: Theorem 1.14 |title=Families of varieties of general type |date=July 20, 2017 |pages=11 |url=https://web.math.princeton.edu/~kollar/book/modbook20170720.pdf }}</ref> Braungardt has posed the question whether [[Belyi's theorem]] can be generalised to varieties of higher dimension over the [[field of algebraic numbers]], with the formulation that they are generally birational to a finite [[étale covering]] of a moduli space of curves.<ref>{{cite book |first=W. |last=Goldring |chapter=Unifying themes suggested by Belyi’s Theorem |chapter-url= |title=Number Theory, Analysis and Geometry |publisher=Springer |date=2012 |isbn=978-1-4614-1260-1 |pages=181–214 See p. 203|doi=10.1007/978-1-4614-1260-1_10}}</ref>

Using the notion of [[stable vector bundle]], coarse moduli schemes for the vector bundles on any smooth [[complex variety]] have been shown to exist, and to be quasi-projective: the statement uses the concept of [[semistable vector bundle|semistability]].<ref>{{cite book|last=Harris |first=Joe |title=Algebraic Geometry: Bowdoin 1985 |chapter=Curves and their moduli |chapter-url=https://books.google.com/books?id=50IECAAAQBAJ&pg=PA103 |year=1987|publisher=American Mathematical Soc.|isbn=978-0-8218-1480-2 |pages=99–143 See p. 103}}</ref> It is possible to identify the coarse moduli space of special [[instanton bundle]]s, in [[mathematical physics]], with objects in the classical geometry of conics, in certain cases.<ref>{{cite book |first1=W. |last1=Böhmer |first2=G. |last2=Trautman |chapter=Special Instanton bundles and Poncelet curves |pages=325–336 |doi=10.1007/BFb0078852 |editor1-last=Greuel|editor1-first=Gert-Martin|editor2-last=Trautmann|editor2-first=Günther|title=Singularities, Representation of Algebras, and Vector Bundles: Proceedings of a Symposium held in Lambrecht/Pfalz, Fed.Rep. of Germany, Dec. 13-17, 1985|series=Lecture Notes in Mathematics |chapter-url=https://books.google.com/books?id=Ukh6CwAAQBAJ&pg=PA336 |date=2006 |volume=1273 |publisher=Springer|isbn=978-3-540-47851-5 }}</ref>