Kurs:Vector bundles and ideal closure operations (MSRI 2012)/Lecture 3/latex

\setcounter{section}{3}

In the last lecture we will focus on the question when are the torsors given by a forcing algebras over a two-dimensional ring affine? We will look at the graded situation to be able to work on the corresponding projective curve.

\zwischenueberschrift{Geometric interpretation in dimension two}

We will restrict now to the two-dimensional homogeneous case in order to work on the corresponding projective curve. We want to find an object over the curve which corresponds to the forcing algebra or its induced torsor.

Let $R$ be a two-dimensional standard-graded normal domain over an algebraically closed field $K$. Let
\mavergleichskette
{\vergleichskette
{ C }
{ = }{ \operatorname{Proj} { \left( R \right) } }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} be the corresponding smooth projective curve and let
\mavergleichskettedisp
{\vergleichskette
{ I }
{ =} { { \left( f_1 , \ldots , f_n \right) } }
{ } { }
{ } { }
{ } { }
} {}{}{} be an $R_+$-primary homogeneous ideal with generators of degrees
\mathl{d_1 , \ldots , d_n}{.} Then we get on $C$ the short exact sequence
\mathdisp {0 \longrightarrow \operatorname{Syz} { \left( f_1 , \ldots , f_n \right) } (m) \longrightarrow \bigoplus_{i=1}^n{\mathcal O}_C(m-d_i) \stackrel{f_1, \ldots ,f_n}{\longrightarrow} {\mathcal O}_C (m) \longrightarrow 0} { . }
Here
\mathl{\operatorname{Syz} { \left( f_1 , \ldots , f_n \right) } (m)}{} is a vector bundle, called the
\betonung{syzygy bundle}{,} of rank
\mathl{n-1}{} and of degree
\mathdisp {((n-1)m - \sum_{i=1}^n d_i) \operatorname{deg} \, (C)} { . }

Thus a homogeneous element $f$ of degree $m$ defines a cohomology class
\mathl{\delta(f) \in H^1(C, \operatorname{ Syz}_{ } ^{ } { \left( f_1 , \ldots , f_n \right) }(m) )}{,} so this defines a torsor over the projective curve.

\zwischenueberschrift{Semistability of vector bundles}

In the situation of a forcing algebra of homogeneous elements, this torsor $T$ can also be obtained as
\mathl{\operatorname{Proj} { \left( B \right) }}{,} where $B$ is the \zusatzklammer {not necessarily positively} {} {} graded forcing algebra. In particular, it follows that the containment
\mavergleichskette
{\vergleichskette
{ f }
{ \in }{ I^* }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} is equivalent to the property that $T$ is not an affine variety. For this properties, positivity (ampleness) properties of the syzygy bundle are crucial. We need the concept of \zusatzklammer {Mumford} {-} {} semistability.

\inputdefinition
{}
{

}

An important property of a semistable bundle of negative degree is that it can not have any global section $\neq 0$. Note that a semistable vector bundle need not be strongly semistable, the following is probably the simplest example.


\inputexample{}
{

}

The following example is related to Beispiel *****.

\inputexample{}
{

}

For a strongly semistable vector bundle ${\mathcal S}$ on $C$ and a cohomology class
\mavergleichskette
{\vergleichskette
{ c }
{ \in }{ H^1(C, {\mathcal S}) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} with corresponding torsor we obtain the following affineness criterion.

\inputfakt{Torsor über Kurve/Stark semistabil/Affinitätskriterium/Fakt/en}{Theorem}{} {

}

This result rests on the ampleness of
\mathl{{\mathcal S}'^\vee}{} occuring in the dual exact sequence
\mathl{0 \rightarrow {\mathcal O}_C \rightarrow {\mathcal S}'^\vee \rightarrow {\mathcal S}^\vee \rightarrow 0}{} given by $c$ \zusatzklammer {this rests on work of Gieseker and Hartshorne(see  \cite{giesekerample},  \cite{hartshorneamplecurve}} {} {.} It implies for a strongly semistable syzygy bundle the following
\betonung{degree formula}{} for tight closure.

\inputfakt{tight closure/degree bound for inclusion/strongly semistable/curve case/Fakt/en}{Theorem}{} {Suppose that
\mathl{\operatorname{Syz} { \left( f_1 , \ldots , f_n \right) }}{} is strongly semistable. Then
\mathdisp {R_m \subseteq I^* \text{ for } m \geq \frac{\sum d_i}{n-1} \text{ and (for almost all prime numbers) } R_m \cap I^* \subseteq I \text{ for } m < \frac{\sum d_i}{n-1}} { . }
}

If we take on the right hand side $I^F$, the \stichwort {Frobenius closure} {} of the ideal, instead of $I$, then this statement is true for all characteristics. As stated, it is true in a relative setting for $p$ large enough.

We indicate the proof of the inclusion result. The degree condition implies that
\mavergleichskette
{\vergleichskette
{ c }
{ \in }{ \delta(f) }
{ = }{ H^1(C, {\mathcal S}) }
{ }{ }
{ }{ }
} {}{}{} is such that
\mavergleichskette
{\vergleichskette
{ {\mathcal S} }
{ = }{ \operatorname{Syz} { \left( f_1 , \ldots , f_n \right) } (m) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} has non-negative degree. Then also all Frobenius pull-backs
\mathl{F^*(\mathcal S)}{} have non-negative degree. Let
\mavergleichskette
{\vergleichskette
{ {\mathcal L} }
{ = }{ {\mathcal O}(k) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} be a twist of the tautological line bundle on $C$ such that its degree is larger than the degree of
\mathl{\omega_C^{-1}}{,} the dual of the canonical sheaf. Let
\mavergleichskette
{\vergleichskette
{ z }
{ \in }{ H^0(Y, {\mathcal L}) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} be a non-zero element. Then
\mavergleichskette
{\vergleichskette
{ z F^{e*}(c) }
{ \in }{ H^1(C, F^{e*}({\mathcal S}) \otimes {\mathcal L}) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} and by Serre duality we have
\mavergleichskettedisp
{\vergleichskette
{ H^1(C, F^{e*} ({\mathcal S}) \otimes {\mathcal L}) }
{ \cong} { H^0 ( F^{e*}({\mathcal S}^{\vee} ) \otimes {\mathcal L}^{-1} \otimes \omega_C)^{\vee} }
{ } { }
{ } { }
{ } { }
} {}{}{.} On the right hand side we have a semistable sheaf of negative degree, which can not have a non-trivial section. Hence
\mavergleichskettedisp
{\vergleichskette
{ zF^{e*} (c) }
{ =} { 0 }
{ } { }
{ } { }
{ } { }
} {}{}{} and therefore $f$ belongs to the tight closure.

\zwischenueberschrift{Harder-Narasimhan filtration}

In general, there exists an exact criterion depending on $c$ and the
\betonung{strong Harder-Narasimhan filtration}{} of ${\mathcal S}$. For this we give the definition of the Harder-Narasimhan filtration.

\inputdefinition
{}
{

}

The Harder-Narasimhan filtration exists uniquely \zusatzklammer {by a Theorem of Harder and Narasimhan} {} {.} A Harder-Narasimhan filtration is called strong if all the quotients
\mathl{{\mathcal S}_{i}/{\mathcal S}_{i-1}}{} are strongly semistable. A Harder-Narasimhan filtration is not strong in general, however, by a Theorem of A. Langer, there exists some Frobenius pull-back
\mathl{F^{e*} ( {\mathcal S} )}{} such that its Harder-Narasimhan filtration is strong.

\inputfakt{Torsor über Kurve/Starke Harder-Narasimhan Filtration/Affinitätskriterium/en/Fakt}{Theorem}{} {

}

\zwischenueberschrift{Plus closure in dimension two}

Let $K$ be a field and let $R$ be a normal two-dimensional standard-graded domain over $K$ with corresponding smooth projective curve $C$. A homogeneous ${\mathfrak m}$-primary ideal with homogeneous ideal generators
\mathl{f_1 , \ldots , f_n}{} and another homogeneous element $f$ of degree $m$ yield a cohomology class
\mavergleichskettedisp
{\vergleichskette
{ c }
{ =} { \delta(f) }
{ =} { H^1(C, \operatorname{Syz} { \left( f_1 , \ldots , f_n \right) } (m)) }
{ } { }
{ } { }
} {}{}{.} Let
\mathl{T(c)}{} be the corresponding torsor. We have seen that the affineness of this torsor over $C$ is equivalent to the affineness of the corresponding torsor over
\mavergleichskette
{\vergleichskette
{ D( {\mathfrak m} ) }
{ \subseteq }{ \operatorname{Spec} { \left( R \right) } }
{ }{ }
{ }{ }
{ }{ }
} {}{}{.} Now we want to understand what the property
\mavergleichskette
{\vergleichskette
{ f }
{ \in }{ I^+ }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} means for $c$ and for
\mathl{T(c)}{.} Instead of the plus closure we will work with the \stichwort {graded plus closure} {}
\mathl{I^{+ \text{gr} }}{,} where
\mavergleichskette
{\vergleichskette
{ f }
{ \in }{ I^{+ \text{gr} } }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} holds if and only if there exists a finite graded extension
\mavergleichskette
{\vergleichskette
{ R }
{ \subseteq }{ S }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} such that
\mavergleichskette
{\vergleichskette
{ f }
{ \in }{ IS }
{ }{ }
{ }{ }
{ }{ }
} {}{}{.} The existence of such an $S$ translates into the existence of a finite morphism \maabbdisp {\varphi} {C'= \operatorname{Proj} { \left( S \right) } } { \operatorname{Proj} { \left( R \right) } = C } {} such that
\mavergleichskette
{\vergleichskette
{ \varphi^*(c) }
{ = }{ 0 }
{ }{ }
{ }{ }
{ }{ }
} {}{}{.} Here we may assume that $C'$ is also smooth. Therefore we discuss the more general question when a cohomology class
\mavergleichskette
{\vergleichskette
{ c }
{ \in }{ H^1(C, {\mathcal S} ) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} where ${\mathcal S}$ is a locally free sheaf on $C$, can be annihilated by a finite morphism \maabbdisp {} {C'} {C } {} of smooth projective curves. The advantage of this more general approach is that we may work with short exact sequences \zusatzklammer {in particular, the sequences coming from the Harder-Narasimhan filtration} {} {} in order to reduce the problem to semistable bundles which do not necessarily come from an ideal situation.

We want to show that the cohomological criterion for \zusatzklammer {non} {} {-}affineness of a torsor along the Harder-Narasimhan filtration of the vector bundle also holds for the existence of projective curves inside the torsor, under the condition that the projective curve is defined over a finite field. This implies that tight closure is \zusatzklammer {graded} {} {} plus closure for graded ${\mathfrak m}$-primary ideals in a two-dimensional graded domain over a finite field.

\zwischenueberschrift{Annihilation of cohomology classes of strongly semistable sheaves}

We deal first with the situation of a strongly semistable sheaf ${\mathcal S}$ of degree $0$. The following two results are due to Lange and Stuhler \cite{langestuhler}. We say that a locally free sheaf is \stichwort {\'{e}tale trivializable} {} if there exists a finite \'{e}tale morphism \maabb {\varphi} {C'} {C } {} such that
\mavergleichskette
{\vergleichskette
{ \varphi^*( {\mathcal S} ) }
{ \cong }{ {\mathcal O}_{ C' }^r }
{ }{ }
{ }{ }
{ }{ }
} {}{}{.} Such bundles are directly related to linear representations of the \'{e}tale fundamental group.

\inputfakt{Endlicher Körper/Glatte projektive Kurve/Vektorbündel/Etale trivialisierbar und Frobenius Periodizität/Fakt/en}{Lemma}{} {

}

\zwischenueberschrift{The general case}

We look now at an arbitrary locally free sheaf ${\mathcal S}$ on $C$, a smooth projective curve over a finite field. We want to show that the same numerical criterion \zusatzklammer {formulated in terms of the Harder-Narasimhan filtration} {} {} for non-affineness of a torsor holds also for the finite annihilation of the corresponding cohomomology class \zusatzklammer {or the existence of a projective curve inside the torsor} {} {.}

These results imply the following theorem in the setting of a two-dimensional graded ring.


\inputfakt{Tight closure/Plus closure/2 dim, standard-graded/Brenner/Fakt/en}{Theorem}{} {

}

This is also true for non-primary graded ideals and also for submodules in finitely generated graded submodules. Moreover, G. Dietz  \cite{dietztight} has shown that one can get rid also of the graded assumption \zusatzklammer {of the ideal or module, but not of the ring} {} {.}

\zwischenueberschrift{Geometric deformations - A counterexample to the localization problem}

Let
\mavergleichskette
{\vergleichskette
{ S }
{ \subseteq }{ R }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} be a multiplicative system and $I$ an ideal in $R$. Then the
\betonung{localization problem}{} of tight closure is the question whether the identity
\mavergleichskettedisp
{\vergleichskette
{ (I^*)_S }
{ =} { (IR_S)^* }
{ } { }
{ } { }
{ } { }
} {}{}{} holds.

Here the inclusion $\subseteq$ is always true and $\supseteq$ is the problem. The problem means explicitly:

\einrueckung{if
\mavergleichskette
{\vergleichskette
{ f }
{ \in }{ (IR_S)^* }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} can we find an
\mavergleichskette
{\vergleichskette
{ h }
{ \in }{ S }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} such that
\mavergleichskette
{\vergleichskette
{ hf }
{ \in }{ I^* }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} holds in $R$?}

In order to get a counterexample to the localization property we will look now at geometric deformations:
\mavergleichskettedisp
{\vergleichskette
{ D }
{ =} { {\mathbb F}_p[t] }
{ \subset} { {\mathbb F}_p[t][x,y,z]/(g) }
{ =} { S }
{ } { }
} {}{}{,} where $t$ has degree $0$ and
\mathl{x,y,z}{} have degree $1$ and $g$ is homogeneous. Then \zusatzklammer {for every field
\mavergleichskettek
{\vergleichskettek
{ {\mathbb F}_p[t] }
{ \subseteq }{ K }
{ }{ }
{ }{ }
{ }{ }
} {}{}{}} {} {}
\mathdisp {S \otimes_{ {\mathbb F}_p [t]} K} { }
is a two-dimensional standard-graded ring over $K$. For residue class fields of points of
\mavergleichskette
{\vergleichskette
{ {\mathbb A}^{1}_{ {\mathbb F}_p } }
{ = }{ \operatorname{Spec} { \left( {\mathbb F}_p [t] \right) } }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} we have basically two possibilities. \auflistungzwei{
\mavergleichskette
{\vergleichskette
{ K }
{ = }{ {\mathbb F}_p (t) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} the function field. This is the
\betonung{generic}{} or
\betonung{transcendental}{} case. }{
\mavergleichskette
{\vergleichskette
{ K }
{ = }{ {\mathbb F}_q }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} the
\betonung{special}{} or
\betonung{algebraic}{} or
\betonung{finite}{} case.}

How does
\mavergleichskette
{\vergleichskette
{ f }
{ \in }{ I^* }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} vary with $K$? To analyze the behavior of tight closure in such a family we can use what we know in the two-dimensional standard-graded situation.

In order to establish an example where tight closure does not behave uniformly under a geometric deformation we first need a situation where strong semistability does not behave uniformly. Such an example was given, in terms of Hilbert-Kunz theory, by Paul Monsky in 1998 \cite{monskypoints4quartics}.

\inputexample{}
{ Let
\mavergleichskettedisp
{\vergleichskette
{ g }
{ =} { z^4 +z ^2xy +z(x^3+y^3) +(t+t^2)x^2y^2 }
{ } { }
{ } { }
{ } { }
} {}{}{.} Consider
\mavergleichskettedisp
{\vergleichskette
{ S }
{ =} { {\mathbb F}_2[t,x,y,z]/(g) }
{ } { }
{ } { }
{ } { }
} {}{}{.} Then Monsky proved the following results on the
\betonung{Hilbert-Kunz multiplicity}{} of the maximal ideal
\mathl{(x,y,z)}{} in
\mathl{S \otimes_{ {\mathbb F}_2[t]} L}{,} $L$ a field:
\mavergleichskettedisp
{\vergleichskette
{ e_{HK} (S \otimes_{\mathbb F_2[t]} L) }
{ =} { \begin{cases} 3 \text{ for } L = {\mathbb F}_2(t) \\ 3 + \frac{1}{4^d } \text{ for } L = {\mathbb F}_q = {\mathbb F}_2(\alpha) , \, (t \mapsto \alpha,\, d = \deg(\alpha)) \, .\end{cases} }
{ } { }
{ } { }
{ } { }
} {}{}{} }

By the geometric interpretation of Hilbert-Kunz theory this means that the restricted cotangent bundle
\mavergleichskettedisp
{\vergleichskette
{ \operatorname{Syz} { \left( x,y,z \right) } }
{ =} { (\Omega_{ {\mathbb P}^{2}_{} }) {{|}}_C }
{ } { }
{ } { }
{ } { }
} {}{}{} is strongly semistable in the transcendental case, but not strongly semistable in the algebraic case. In fact, for
\mavergleichskette
{\vergleichskette
{ d }
{ = }{ \deg(\alpha) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,}
\mathl{t \mapsto \alpha}{,} where
\mavergleichskette
{\vergleichskette
{ L }
{ = }{ \mathbb F_2(\alpha) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} the $d$-th Frobenius pull-back destabilizes \zusatzklammer {meaning that it is not semistable anymore} {} {.}

The maximal ideal
\mathl{(x,y,z)}{} can not be used directly. However, we look at the second Frobenius pull-back which is \zusatzklammer {characteristic two} {} {} just
\mavergleichskettedisp
{\vergleichskette
{ I }
{ =} { { \left( x^4,y^4,z^4 \right) } }
{ } { }
{ } { }
{ } { }
} {}{}{.} By the degree formula we have to look for an element of degree $6$. Let's take
\mavergleichskette
{\vergleichskette
{ f }
{ = }{ y^3z^3 }
{ }{ }
{ }{ }
{ }{ }
} {}{}{.} This is our example \zusatzklammer {\mathlk{x^3y^3}{} does not work} {} {.} First, by strong semistability in the transcendental case we have
\mathdisp {f \in I^* \text{ in } S \otimes {\mathbb F}_2(t)} { }
by the degree formula. If localization would hold, then $f$ would also belong to the tight closure of $I$ for almost all algebraic instances
\mavergleichskette
{\vergleichskette
{ {\mathbb F}_q }
{ = }{ {\mathbb F}_2(\alpha) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,}
\mathl{t \mapsto \alpha}{.} Contrary to that we show that for all algebraic instances the element $f$ belongs never to the tight closure of $I$.

In terms of affineness \zusatzklammer {or local cohomology} {} {} this example has the following properties: the ideal
\mavergleichskettedisp
{\vergleichskette
{ (x,y,z) }
{ \subseteq} { {\mathbb F}_2(t)[x,y,z,s_1,s_2,s_3]/ { \left( g, s_1x^4+s_2y^4+s_3z^4+ y^3z^3 \right) } }
{ } { }
{ } { }
{ } { }
} {}{}{} has cohomological dimension $1$ if $t$ is transcendental and has cohomological dimension $0$ \zusatzklammer {equivalently, \mathlk{D(x,y,z)}{} is an affine scheme} {} {} if $t$ is algebraic.

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