4
$\begingroup$

In order to construct the coarse moduli scheme of smooth projective curves of genus $g$, the classical results of Mumford (using the numerical criterion of stability) say that for large enough $m$, the $m$-th Hilbert point of a curve is stable. If I understand correctly, this implies that the Hilbert scheme $H_m$ of $m$-canonical curves has a good quotient by the action of the relevant $PGL$ group, namely $PGL_{(2m-1)(g-1)}$. However, people usually deduce also that the Hilbert scheme $H_3$ of tricanonical curves has a good quotient by $PGL_{5(g-1)}$ (this is the claim e.g. in the 1969 paper of Deligne and Mumford). I am probably missing something here: why is it so?

$\endgroup$

2 Answers 2

4
$\begingroup$

I do not believe the result about stability of tricanonical curves is a formal consequence of asymptotic stability. Rather, I think that the explicit arguments that prove $m$-stability for $m\gg 0$, in fact, already apply if m ≥ 3 if $m\geq 5$. The standard reference is the following.

MR0450272 (56 #8568) Reviewed
Mumford, David
Stability of projective varieties.
Enseignement Math. (2) 23 (1977), no. 1-2, 39–110.
14D20

Edit. I had misread Matthieu's question, which asks about smooth curves. In the paper above, Mumford proves $m$-stability of "Deligne-Mumford stable curves" for $m\geq 5$. For the argument for smooth curves and $m\geq 3$, see the next edit.

Second edit. Using the classical "Weierstrass Gap Theorem", in Section 4.6, Theorem 4.5, p. 95 of "Geometric Invariant Theory, 3rd ed.", Mumford proves Chow stability of every smooth curve of genus $g>1$ embedded in $\mathbb{P}^n$ by a complete linear system of degree $\geq 3g$ (also the open subscheme of Chow parameterizing smooth curves is canonically isomorphic to the corresponding open subscheme of the Hilbert scheme). So for $g\geq 3$, already bicanonically embedded curves are stable (in particular, the bicanonical morphism is an embedding). For $g=2$, the bicanonical morphism is not an embedding: it is the composition of the canonical map to $\mathbb{P}^1$ with a Veronese map $\mathbb{P}^1\to \mathbb{P}^2$. Thus, if you want to include $g=2$, you need the tricanonical embedding.

So why doesn't Mumford say this explicitly in Chapter 5 of GIT? For one thing, at the time GIT was not sufficient to construct the coarse moduli space $M_g$ as a quasi-projective scheme over $\text{Spec}(\mathbb{Z})$, so the stability issue was a bit irrelevant (at that time). There were problems in positive characteristic (see the work of Haboush) and over $\text{Spec}(\mathbb{Z})$ (see the work of Seshadri). Happily, Mumford was able to avoid all of this by instead using some explicit invariant theory constructions that, essentially, avoid GIT altogether. This is the great irony of GIT: even though it is an indispensable tool in algebraic geometry, Mumford's first construction of $M_g$ really doesn't use GIT at all.

$\endgroup$
9
  • $\begingroup$ Well, but firstly Deligne and Mumford published their paper in 1969 (8 years before [SPV]:=Stability of proj. var.) and secondly, when you read [SPV], you see plenty of arguments that really work only for $m\gg 0$! $\endgroup$ Dec 2, 2013 at 8:33
  • $\begingroup$ ps: quote from Deligne and Mumford: "By the results of [M1] (=Mumford's GIT book), we know that a coarse geometric quotient $M_g^0=H_g^0/PGL(5g-6)$ exists (...)". $\endgroup$ Dec 2, 2013 at 8:36
  • $\begingroup$ Wait, are you looking only at the parameter space for smooth curves? $\endgroup$ Dec 2, 2013 at 12:17
  • $\begingroup$ Yes, as I wrote in the question. $\endgroup$ Dec 2, 2013 at 13:46
  • 1
    $\begingroup$ Dear Jason, this discussion was very useful. I suggest that you post an answer to tell about the two constructions in Mumford's book, telling that the first does not prove that $M_g$ is a quotient of the tricanonical Hilbert scheme but that the second one (using moduli of abelian varieties) does prove it. I'll accept this answer. $\endgroup$ Dec 2, 2013 at 15:49
2
$\begingroup$

In that Deligne-Mumford's paper they proved stability for m≥5*. To consider the pluricanonical embedding $\omega_C^m$ with $m=3$ gives a different compactification of $M_g$. In particular cusps are stable and elliptic tails are unstable. This case was worked out by Schubert (a Gieseker student). The article is: A new compactification of the moduli space of curves D Schubert - Compositio Math, 1991

http://archive.numdam.org/ARCHIVE/CM/CM_1991__78_3/CM_1991__78_3_297_0/CM_1991__78_3_297_0.pdf

Finally, notice it is not obvious that the GIT quotient stabilizes (i.e it is the same for $m>>0$). This stabilization does not hold in some higher dimensional cases.

$\endgroup$
5
  • $\begingroup$ Yes, I also noted in my earlier edit that the result is for $m\geq 5$. $\endgroup$ Dec 2, 2013 at 15:30
  • $\begingroup$ Does not quite answer my question, but that's interesting, thanks. $\endgroup$ Dec 2, 2013 at 15:50
  • $\begingroup$ dear Matthieu, I am bit confused! You asked "people usually deduce also that the Hilbert scheme H3 of tricanonical curves has a good quotient by PGL5(g−1)..why is it so?". I have the impression that the Schubert's article constructs that GIT quotient. $\endgroup$
    – eventually
    Dec 2, 2013 at 17:20
  • $\begingroup$ Dear pmath, let me just emphasize that my question was about the way one deduces (if possible, which apparently is not the case) 3-stability from $m$-stability. Also, my question was only about smooth curves and had nothing to do with compactifications. However, your answer is certainly interesting and related to other aspects of GIT stability that are implicit in my question. $\endgroup$ Dec 2, 2013 at 20:44
  • $\begingroup$ You are right, it is my mistake. However, I think that Theorem 5.1 and Lemma 5.2 of Schubert's article answer your question. $\endgroup$
    – eventually
    Dec 2, 2013 at 21:37

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.