Post on 30-Jun-2020
Birational geometry and moduli
spaces of varieties of general type
James McKernan
UCSD
Birational geometry and moduli spaces of varieties of general type – p. 1
Birational classification
Roughly speaking varieties come in three types:
Birational geometry and moduli spaces of varieties of general type – p. 2
Birational classification
Roughly speaking varieties come in three types:
• KX negative: P1, del Pezzos, low degree in Pn.
Birational geometry and moduli spaces of varieties of general type – p. 2
Birational classification
Roughly speaking varieties come in three types:
• KX negative: P1, del Pezzos, low degree in Pn.
• Quite rare; relatively simple geometry; explicitclassification is sometimes feasible.
Birational geometry and moduli spaces of varieties of general type – p. 2
Birational classification
Roughly speaking varieties come in three types:
• KX negative: P1, del Pezzos, low degree in Pn.
• Quite rare; relatively simple geometry; explicitclassification is sometimes feasible.
• KX zero: elliptic curves, K3, Calabi-Yau, HKM.
Birational geometry and moduli spaces of varieties of general type – p. 2
Birational classification
Roughly speaking varieties come in three types:
• KX negative: P1, del Pezzos, low degree in Pn.
• Quite rare; relatively simple geometry; explicitclassification is sometimes feasible.
• KX zero: elliptic curves, K3, Calabi-Yau, HKM.
• Rich geometry; are CY threefolds bounded? How isthis related to bounding b2 and b3?
Birational geometry and moduli spaces of varieties of general type – p. 2
Birational classification
Roughly speaking varieties come in three types:
• KX negative: P1, del Pezzos, low degree in Pn.
• Quite rare; relatively simple geometry; explicitclassification is sometimes feasible.
• KX zero: elliptic curves, K3, Calabi-Yau, HKM.
• Rich geometry; are CY threefolds bounded? How isthis related to bounding b2 and b3?
• KX positive: curves g ≥ 2, large degree in Pn.
Birational geometry and moduli spaces of varieties of general type – p. 2
Birational classification
Roughly speaking varieties come in three types:
• KX negative: P1, del Pezzos, low degree in Pn.
• Quite rare; relatively simple geometry; explicitclassification is sometimes feasible.
• KX zero: elliptic curves, K3, Calabi-Yau, HKM.
• Rich geometry; are CY threefolds bounded? How isthis related to bounding b2 and b3?
• KX positive: curves g ≥ 2, large degree in Pn.
• Form continuous families. Try to construct modulispaces and investigate their geometry.
Birational geometry and moduli spaces of varieties of general type – p. 2
Birational classification
Roughly speaking varieties come in three types:
• KX negative: P1, del Pezzos, low degree in Pn.
• Quite rare; relatively simple geometry; explicitclassification is sometimes feasible.
• KX zero: elliptic curves, K3, Calabi-Yau, HKM.
• Rich geometry; are CY threefolds bounded? How isthis related to bounding b2 and b3?
• KX positive: curves g ≥ 2, large degree in Pn.
• Form continuous families. Try to construct modulispaces and investigate their geometry.
• KX is a natural polarisation on a curve of g ≥ 2. Ingeneral classification is a birational problem.
Birational geometry and moduli spaces of varieties of general type – p. 2
Moduli space of curves
The moduli space Mg of stable curves is one of themost heavily studied varieties in algebraic geometry.It has a very well behaved geometry:
Birational geometry and moduli spaces of varieties of general type – p. 3
Moduli space of curves
The moduli space Mg of stable curves is one of themost heavily studied varieties in algebraic geometry.It has a very well behaved geometry:
• it is integral; reduced and irreducible. In particular,every stable nodal curve can be smoothed.
Birational geometry and moduli spaces of varieties of general type – p. 3
Moduli space of curves
The moduli space Mg of stable curves is one of themost heavily studied varieties in algebraic geometry.It has a very well behaved geometry:
• it is integral; reduced and irreducible. In particular,every stable nodal curve can be smoothed.
• it is projective; proper and has an ample line bundle.
Birational geometry and moduli spaces of varieties of general type – p. 3
Moduli space of curves
The moduli space Mg of stable curves is one of themost heavily studied varieties in algebraic geometry.It has a very well behaved geometry:
• it is integral; reduced and irreducible. In particular,every stable nodal curve can be smoothed.
• it is projective; proper and has an ample line bundle.
• it has quotient singularities; even better it is globallythe quotient of a smooth projective variety (ACV).
Birational geometry and moduli spaces of varieties of general type – p. 3
Moduli space of curves
The moduli space Mg of stable curves is one of themost heavily studied varieties in algebraic geometry.It has a very well behaved geometry:
• it is integral; reduced and irreducible. In particular,every stable nodal curve can be smoothed.
• it is projective; proper and has an ample line bundle.
• it has quotient singularities; even better it is globallythe quotient of a smooth projective variety (ACV).
• every pluricanonical form lifts to a resolution (even
though Mg is not canonical).
Birational geometry and moduli spaces of varieties of general type – p. 3
Moduli space of curves
The moduli space Mg of stable curves is one of themost heavily studied varieties in algebraic geometry.It has a very well behaved geometry:
• it is integral; reduced and irreducible. In particular,every stable nodal curve can be smoothed.
• it is projective; proper and has an ample line bundle.
• it has quotient singularities; even better it is globallythe quotient of a smooth projective variety (ACV).
• every pluricanonical form lifts to a resolution (even
though Mg is not canonical).
• KMg+D is log canonical and ample, where D is the
sum of the boundary divisors, ∂Mg = Mg −Mg.Birational geometry and moduli spaces of varieties of general type – p. 3
New directions
Mg,n the moduli space of stable curves of genus gwith n marked points.
Birational geometry and moduli spaces of varieties of general type – p. 4
New directions
Mg,n the moduli space of stable curves of genus gwith n marked points.
Mg,n(X, β) the moduli space of stable maps to a
projective variety X .
Birational geometry and moduli spaces of varieties of general type – p. 4
New directions
Mg,n the moduli space of stable curves of genus gwith n marked points.
Mg,n(X, β) the moduli space of stable maps to a
projective variety X .
Moduli of abelian varieties, moduli of vectorbundles, Bridgeland stability conditions, moduli ofFanos with Kähler-Einstein metrics, . . . .
Birational geometry and moduli spaces of varieties of general type – p. 4
New directions
Mg,n the moduli space of stable curves of genus gwith n marked points.
Mg,n(X, β) the moduli space of stable maps to a
projective variety X .
Moduli of abelian varieties, moduli of vectorbundles, Bridgeland stability conditions, moduli ofFanos with Kähler-Einstein metrics, . . . .
Moduli of varieties of general type of higherdimension. We will focus on this moduli space:
Birational geometry and moduli spaces of varieties of general type – p. 4
New directions
Mg,n the moduli space of stable curves of genus gwith n marked points.
Mg,n(X, β) the moduli space of stable maps to a
projective variety X .
Moduli of abelian varieties, moduli of vectorbundles, Bridgeland stability conditions, moduli ofFanos with Kähler-Einstein metrics, . . . .
Moduli of varieties of general type of higherdimension. We will focus on this moduli space:
• projective X , KX is ample (canonically polarised).
Birational geometry and moduli spaces of varieties of general type – p. 4
New directions
Mg,n the moduli space of stable curves of genus gwith n marked points.
Mg,n(X, β) the moduli space of stable maps to a
projective variety X .
Moduli of abelian varieties, moduli of vectorbundles, Bridgeland stability conditions, moduli ofFanos with Kähler-Einstein metrics, . . . .
Moduli of varieties of general type of higherdimension. We will focus on this moduli space:
• projective X , KX is ample (canonically polarised).
• more generally log canonical pairs (X,∆) such that
KX +∆ is ample (from Mg to Mg,n).Birational geometry and moduli spaces of varieties of general type – p. 4
First results
Gieseker showed that the set of smooth projectivesurfaces S of general type with fixed Hilbert
polynomial h(t) = χ(S,OS(tKS)) is the set of
closed point of a quasi-projective variety M(h).
Birational geometry and moduli spaces of varieties of general type – p. 5
First results
Gieseker showed that the set of smooth projectivesurfaces S of general type with fixed Hilbert
polynomial h(t) = χ(S,OS(tKS)) is the set of
closed point of a quasi-projective variety M(h).
The method of proof is quite delicate and based onMumford’s Geometric Invariant Theory.
Birational geometry and moduli spaces of varieties of general type – p. 5
First results
Gieseker showed that the set of smooth projectivesurfaces S of general type with fixed Hilbert
polynomial h(t) = χ(S,OS(tKS)) is the set of
closed point of a quasi-projective variety M(h).
The method of proof is quite delicate and based onMumford’s Geometric Invariant Theory.
Viehweg generalised this to smooth projectivevarieties with ample canonical divisor KX .
Birational geometry and moduli spaces of varieties of general type – p. 5
First results
Gieseker showed that the set of smooth projectivesurfaces S of general type with fixed Hilbert
polynomial h(t) = χ(S,OS(tKS)) is the set of
closed point of a quasi-projective variety M(h).
The method of proof is quite delicate and based onMumford’s Geometric Invariant Theory.
Viehweg generalised this to smooth projectivevarieties with ample canonical divisor KX .
The focus of the construction moves away from GIT.
Birational geometry and moduli spaces of varieties of general type – p. 5
First results
Gieseker showed that the set of smooth projectivesurfaces S of general type with fixed Hilbert
polynomial h(t) = χ(S,OS(tKS)) is the set of
closed point of a quasi-projective variety M(h).
The method of proof is quite delicate and based onMumford’s Geometric Invariant Theory.
Viehweg generalised this to smooth projectivevarieties with ample canonical divisor KX .
The focus of the construction moves away from GIT.
Viehweg’s results apply to singular projectivevarieties with ample canonical divisor and rationalGorenstein singularities (= canonical + KX Cartier).
Birational geometry and moduli spaces of varieties of general type – p. 5
First results
Gieseker showed that the set of smooth projectivesurfaces S of general type with fixed Hilbert
polynomial h(t) = χ(S,OS(tKS)) is the set of
closed point of a quasi-projective variety M(h).
The method of proof is quite delicate and based onMumford’s Geometric Invariant Theory.
Viehweg generalised this to smooth projectivevarieties with ample canonical divisor KX .
The focus of the construction moves away from GIT.
Viehweg’s results apply to singular projectivevarieties with ample canonical divisor and rationalGorenstein singularities (= canonical + KX Cartier).
Call this the smooth case. Birational geometry and moduli spaces of varieties of general type – p. 5
Murphy’s law
Vakil showed that these moduli spaces satisfyMurphy’s law:
Birational geometry and moduli spaces of varieties of general type – p. 6
Murphy’s law
Vakil showed that these moduli spaces satisfyMurphy’s law:
Fix any scheme Z of finite type over SpecZ. Thereis a moduli space of smooth projective surfaces withvery ample canonical divisor which is locally (in thesmooth topology) isomorphic to Z. In particular:
Birational geometry and moduli spaces of varieties of general type – p. 6
Murphy’s law
Vakil showed that these moduli spaces satisfyMurphy’s law:
Fix any scheme Z of finite type over SpecZ. Thereis a moduli space of smooth projective surfaces withvery ample canonical divisor which is locally (in thesmooth topology) isomorphic to Z. In particular:
• The moduli space has arbitrarily many components:
Z = SpecZ[x, y]/〈(x− y)(x− 2y)(x− 3y) . . . 〉.
Birational geometry and moduli spaces of varieties of general type – p. 6
Murphy’s law
Vakil showed that these moduli spaces satisfyMurphy’s law:
Fix any scheme Z of finite type over SpecZ. Thereis a moduli space of smooth projective surfaces withvery ample canonical divisor which is locally (in thesmooth topology) isomorphic to Z. In particular:
• The moduli space has arbitrarily many components:
Z = SpecZ[x, y]/〈(x− y)(x− 2y)(x− 3y) . . . 〉.
• The moduli space is non-reduced:
Z = SpecZ[x]/〈xn〉.
Birational geometry and moduli spaces of varieties of general type – p. 6
Murphy’s law
Vakil showed that these moduli spaces satisfyMurphy’s law:
Fix any scheme Z of finite type over SpecZ. Thereis a moduli space of smooth projective surfaces withvery ample canonical divisor which is locally (in thesmooth topology) isomorphic to Z. In particular:
• The moduli space has arbitrarily many components:
Z = SpecZ[x, y]/〈(x− y)(x− 2y)(x− 3y) . . . 〉.
• The moduli space is non-reduced:
Z = SpecZ[x]/〈xn〉.
• The moduli space has arbitrarily bad singularities.
Birational geometry and moduli spaces of varieties of general type – p. 6
Murphy’s law
Vakil showed that these moduli spaces satisfyMurphy’s law:
Fix any scheme Z of finite type over SpecZ. Thereis a moduli space of smooth projective surfaces withvery ample canonical divisor which is locally (in thesmooth topology) isomorphic to Z. In particular:
• The moduli space has arbitrarily many components:
Z = SpecZ[x, y]/〈(x− y)(x− 2y)(x− 3y) . . . 〉.
• The moduli space is non-reduced:
Z = SpecZ[x]/〈xn〉.
• The moduli space has arbitrarily bad singularities.
Moral: we should expect many complications inhigher dimensions. Birational geometry and moduli spaces of varieties of general type – p. 6
Construction of Mg
Let’s first review the construction of Mg.
Birational geometry and moduli spaces of varieties of general type – p. 7
Construction of Mg
Let’s first review the construction of Mg.
Every smooth curve C of genus g ≥ 2 is embedded
in P5g−6 by the linear system |3KC | as a curve ofdegree 6g − 6.
Birational geometry and moduli spaces of varieties of general type – p. 7
Construction of Mg
Let’s first review the construction of Mg.
Every smooth curve C of genus g ≥ 2 is embedded
in P5g−6 by the linear system |3KC | as a curve ofdegree 6g − 6.
The family of all curves of degree 6g − 6 in P5g−6 isa quasi-projective scheme, using the Hilbert scheme(Grothendieck).
Birational geometry and moduli spaces of varieties of general type – p. 7
Construction of Mg
Let’s first review the construction of Mg.
Every smooth curve C of genus g ≥ 2 is embedded
in P5g−6 by the linear system |3KC | as a curve ofdegree 6g − 6.
The family of all curves of degree 6g − 6 in P5g−6 isa quasi-projective scheme, using the Hilbert scheme(Grothendieck).
The family of all smooth curves embedded by |3KC |is a locally closed subset.
Birational geometry and moduli spaces of varieties of general type – p. 7
Construction of Mg
Let’s first review the construction of Mg.
Every smooth curve C of genus g ≥ 2 is embedded
in P5g−6 by the linear system |3KC | as a curve ofdegree 6g − 6.
The family of all curves of degree 6g − 6 in P5g−6 isa quasi-projective scheme, using the Hilbert scheme(Grothendieck).
The family of all smooth curves embedded by |3KC |is a locally closed subset.
(Mumford) Realise Mg as a GIT quotient by the
action of PGL(5g − 5).
Birational geometry and moduli spaces of varieties of general type – p. 7
Construction of Mg
Take a GIT quotient of the space of 5-canonically
embedded curves of genus g in P9g−10.
Birational geometry and moduli spaces of varieties of general type – p. 8
Construction of Mg
Take a GIT quotient of the space of 5-canonically
embedded curves of genus g in P9g−10.
Identifying the isomorphism classes of points of the
boundary ∂Mg = Mg −Mg is very subtle.
Birational geometry and moduli spaces of varieties of general type – p. 8
Construction of Mg
Take a GIT quotient of the space of 5-canonically
embedded curves of genus g in P9g−10.
Identifying the isomorphism classes of points of the
boundary ∂Mg = Mg −Mg is very subtle.
A delicate and beautiful argument that seems next toimpossible to generalise to higher dimensions.
Birational geometry and moduli spaces of varieties of general type – p. 8
Construction of Mg
Take a GIT quotient of the space of 5-canonically
embedded curves of genus g in P9g−10.
Identifying the isomorphism classes of points of the
boundary ∂Mg = Mg −Mg is very subtle.
A delicate and beautiful argument that seems next toimpossible to generalise to higher dimensions.
Closed points of Mg correspond to stable curves(stable in the sense of both semi-stable reductionand GIT):
Birational geometry and moduli spaces of varieties of general type – p. 8
Construction of Mg
Take a GIT quotient of the space of 5-canonically
embedded curves of genus g in P9g−10.
Identifying the isomorphism classes of points of the
boundary ∂Mg = Mg −Mg is very subtle.
A delicate and beautiful argument that seems next toimpossible to generalise to higher dimensions.
Closed points of Mg correspond to stable curves(stable in the sense of both semi-stable reductionand GIT):
• C is nodal and KC is ample.
Birational geometry and moduli spaces of varieties of general type – p. 8
Construction of Mg
Take a GIT quotient of the space of 5-canonically
embedded curves of genus g in P9g−10.
Identifying the isomorphism classes of points of the
boundary ∂Mg = Mg −Mg is very subtle.
A delicate and beautiful argument that seems next toimpossible to generalise to higher dimensions.
Closed points of Mg correspond to stable curves(stable in the sense of both semi-stable reductionand GIT):
• C is nodal and KC is ample.
• Equivalently: C is nodal and Aut(C) is finite.
Birational geometry and moduli spaces of varieties of general type – p. 8
Semi-stable reduction for curves
Start with a family of curves S −→ D over the disc,with a singular central fibre.
Birational geometry and moduli spaces of varieties of general type – p. 9
Semi-stable reduction for curves
Start with a family of curves S −→ D over the disc,with a singular central fibre.
Base change z −→ zm, D −→ D, so that there is a
desingularisation S ′ of S ×DD with reduced fibres
over D.
Birational geometry and moduli spaces of varieties of general type – p. 9
Semi-stable reduction for curves
Start with a family of curves S −→ D over the disc,with a singular central fibre.
Base change z −→ zm, D −→ D, so that there is a
desingularisation S ′ of S ×DD with reduced fibres
over D.
Contract S ′ −→ T ′ all −1-curves in the central fibre(run KS′-MMP). KT ′ is nef and T ′ is smooth.
Birational geometry and moduli spaces of varieties of general type – p. 9
Semi-stable reduction for curves
Start with a family of curves S −→ D over the disc,with a singular central fibre.
Base change z −→ zm, D −→ D, so that there is a
desingularisation S ′ of S ×DD with reduced fibres
over D.
Contract S ′ −→ T ′ all −1-curves in the central fibre(run KS′-MMP). KT ′ is nef and T ′ is smooth.
Contract T ′ −→ T all −2-curves. KT is ample andT has canonical (aka ADE, Du Val) singularities.
Birational geometry and moduli spaces of varieties of general type – p. 9
Semi-stable reduction for curves
Start with a family of curves S −→ D over the disc,with a singular central fibre.
Base change z −→ zm, D −→ D, so that there is a
desingularisation S ′ of S ×DD with reduced fibres
over D.
Contract S ′ −→ T ′ all −1-curves in the central fibre(run KS′-MMP). KT ′ is nef and T ′ is smooth.
Contract T ′ −→ T all −2-curves. KT is ample andT has canonical (aka ADE, Du Val) singularities.
Note that T is the relative canonical model of S ′.
Birational geometry and moduli spaces of varieties of general type – p. 9
Semi-stable reduction for curves
Start with a family of curves S −→ D over the disc,with a singular central fibre.
Base change z −→ zm, D −→ D, so that there is a
desingularisation S ′ of S ×DD with reduced fibres
over D.
Contract S ′ −→ T ′ all −1-curves in the central fibre(run KS′-MMP). KT ′ is nef and T ′ is smooth.
Contract T ′ −→ T all −2-curves. KT is ample andT has canonical (aka ADE, Du Val) singularities.
Note that T is the relative canonical model of S ′.
This implies uniqueness of semi-stable reductionand highlights the significance of general type.
Birational geometry and moduli spaces of varieties of general type – p. 9
New approach
Kollár & Shepherd-Barron: eliminate use of GIT,use semi-stable reduction and the MMP instead.
Birational geometry and moduli spaces of varieties of general type – p. 10
New approach
Kollár & Shepherd-Barron: eliminate use of GIT,use semi-stable reduction and the MMP instead.
This program raises many technical and interestingproblems: many contributions from many sources.
Birational geometry and moduli spaces of varieties of general type – p. 10
New approach
Kollár & Shepherd-Barron: eliminate use of GIT,use semi-stable reduction and the MMP instead.
This program raises many technical and interestingproblems: many contributions from many sources.
First big success: Alexeev proved boundedness forsurfaces. This completed (for the most part) theconstruction of the moduli space of surfaces.
Birational geometry and moduli spaces of varieties of general type – p. 10
New approach
Kollár & Shepherd-Barron: eliminate use of GIT,use semi-stable reduction and the MMP instead.
This program raises many technical and interestingproblems: many contributions from many sources.
First big success: Alexeev proved boundedness forsurfaces. This completed (for the most part) theconstruction of the moduli space of surfaces.
There are now two directions in which to head.
Birational geometry and moduli spaces of varieties of general type – p. 10
New approach
Kollár & Shepherd-Barron: eliminate use of GIT,use semi-stable reduction and the MMP instead.
This program raises many technical and interestingproblems: many contributions from many sources.
First big success: Alexeev proved boundedness forsurfaces. This completed (for the most part) theconstruction of the moduli space of surfaces.
There are now two directions in which to head.
• Study explicit examples of moduli of surfaces ofgeneral type—reveals extremely rich geometry.
Birational geometry and moduli spaces of varieties of general type – p. 10
New approach
Kollár & Shepherd-Barron: eliminate use of GIT,use semi-stable reduction and the MMP instead.
This program raises many technical and interestingproblems: many contributions from many sources.
First big success: Alexeev proved boundedness forsurfaces. This completed (for the most part) theconstruction of the moduli space of surfaces.
There are now two directions in which to head.
• Study explicit examples of moduli of surfaces ofgeneral type—reveals extremely rich geometry.
• Try to generalise these results to all dimensions.
Birational geometry and moduli spaces of varieties of general type – p. 10
New approach
Kollár & Shepherd-Barron: eliminate use of GIT,use semi-stable reduction and the MMP instead.
This program raises many technical and interestingproblems: many contributions from many sources.
First big success: Alexeev proved boundedness forsurfaces. This completed (for the most part) theconstruction of the moduli space of surfaces.
There are now two directions in which to head.
• Study explicit examples of moduli of surfaces ofgeneral type—reveals extremely rich geometry.
• Try to generalise these results to all dimensions.
Focus on the latter problem in these lectures.Birational geometry and moduli spaces of varieties of general type – p. 10
Interlude: Explicit Examples
Hacking: plane curves C of degree d > 3.
Birational geometry and moduli spaces of varieties of general type – p. 11
Interlude: Explicit Examples
Hacking: plane curves C of degree d > 3.
Look at the component of the moduli space of log
pairs containing (P2, (3+ǫ)d
C) where ǫ > 0 is
sufficiently small (float the coefficients).
Birational geometry and moduli spaces of varieties of general type – p. 11
Interlude: Explicit Examples
Hacking: plane curves C of degree d > 3.
Look at the component of the moduli space of log
pairs containing (P2, (3+ǫ)d
C) where ǫ > 0 is
sufficiently small (float the coefficients).
Keel, Hacking, Tevelev: cubic surfaces S.
Birational geometry and moduli spaces of varieties of general type – p. 11
Interlude: Explicit Examples
Hacking: plane curves C of degree d > 3.
Look at the component of the moduli space of log
pairs containing (P2, (3+ǫ)d
C) where ǫ > 0 is
sufficiently small (float the coefficients).
Keel, Hacking, Tevelev: cubic surfaces S.
Look at the component of the moduli space of log
pairs containing (S, L1 + L2 + · · ·+ L27), whereL1, L2, . . . , L27 are the 27 lines on the cubic surface.
Birational geometry and moduli spaces of varieties of general type – p. 11
Interlude: Explicit Examples
Hacking: plane curves C of degree d > 3.
Look at the component of the moduli space of log
pairs containing (P2, (3+ǫ)d
C) where ǫ > 0 is
sufficiently small (float the coefficients).
Keel, Hacking, Tevelev: cubic surfaces S.
Look at the component of the moduli space of log
pairs containing (S, L1 + L2 + · · ·+ L27), whereL1, L2, . . . , L27 are the 27 lines on the cubic surface.
Note KS + L1 + L2 + · · ·+ L27 = −8KS is ample.
Birational geometry and moduli spaces of varieties of general type – p. 11
Interlude: Explicit Examples
Hacking: plane curves C of degree d > 3.
Look at the component of the moduli space of log
pairs containing (P2, (3+ǫ)d
C) where ǫ > 0 is
sufficiently small (float the coefficients).
Keel, Hacking, Tevelev: cubic surfaces S.
Look at the component of the moduli space of log
pairs containing (S, L1 + L2 + · · ·+ L27), whereL1, L2, . . . , L27 are the 27 lines on the cubic surface.
Note KS + L1 + L2 + · · ·+ L27 = −8KS is ample.
Sekiguchi: A cubic surface is determined by thej-invariants of all intersections of any line with anyother four lines.
Birational geometry and moduli spaces of varieties of general type – p. 11
Construction of smooth moduli space
(Kollár and Karu) Start with a smooth projectivevariety Y of general type (KY is big) of dim n:
Birational geometry and moduli spaces of varieties of general type – p. 12
Construction of smooth moduli space
(Kollár and Karu) Start with a smooth projectivevariety Y of general type (KY is big) of dim n:
Theorem: (BCHM, Siu) The canonical ring
R(Y,KY ) =⊕
m∈NH0(Y,OY (mKY )) is finitely
generated.
Birational geometry and moduli spaces of varieties of general type – p. 12
Construction of smooth moduli space
(Kollár and Karu) Start with a smooth projectivevariety Y of general type (KY is big) of dim n:
Theorem: (BCHM, Siu) The canonical ring
R(Y,KY ) =⊕
m∈NH0(Y,OY (mKY )) is finitely
generated.
As a consequence every variety Y of general type isbirational φmKY
: Y 99K X ⊂ Pr to a variety Xnaturally embedded in Pr, where KX is ample andX has canonical singularities (Reid).
Birational geometry and moduli spaces of varieties of general type – p. 12
Construction of smooth moduli space
(Kollár and Karu) Start with a smooth projectivevariety Y of general type (KY is big) of dim n:
Theorem: (BCHM, Siu) The canonical ring
R(Y,KY ) =⊕
m∈NH0(Y,OY (mKY )) is finitely
generated.
As a consequence every variety Y of general type isbirational φmKY
: Y 99K X ⊂ Pr to a variety Xnaturally embedded in Pr, where KX is ample andX has canonical singularities (Reid).
Theorem: (Hacon-, Takayama, Tsuji) Fix n. There isa positive integer m0 such that φmKY
is birational forall m ≥ m0.
Birational geometry and moduli spaces of varieties of general type – p. 12
Construction of smooth moduli space
(Kollár and Karu) Start with a smooth projectivevariety Y of general type (KY is big) of dim n:
Theorem: (BCHM, Siu) The canonical ring
R(Y,KY ) =⊕
m∈NH0(Y,OY (mKY )) is finitely
generated.
As a consequence every variety Y of general type isbirational φmKY
: Y 99K X ⊂ Pr to a variety Xnaturally embedded in Pr, where KX is ample andX has canonical singularities (Reid).
Theorem: (Hacon-, Takayama, Tsuji) Fix n. There isa positive integer m0 such that φmKY
is birational forall m ≥ m0.
For curves m0 = 3 works, surfaces m0 = 5.Birational geometry and moduli spaces of varieties of general type – p. 12
Degree versus Hilbert polynomial
Suppose that we fix the volume of KY ,
d = vol(Y,KY ) = lim supm→∞
n!H0(Y,OY (mKY ))
mn.
Birational geometry and moduli spaces of varieties of general type – p. 13
Degree versus Hilbert polynomial
Suppose that we fix the volume of KY ,
d = vol(Y,KY ) = lim supm→∞
n!H0(Y,OY (mKY ))
mn.
Fix m ≥ m0. The degree of X in Pr is at most mnd.
Birational geometry and moduli spaces of varieties of general type – p. 13
Degree versus Hilbert polynomial
Suppose that we fix the volume of KY ,
d = vol(Y,KY ) = lim supm→∞
n!H0(Y,OY (mKY ))
mn.
Fix m ≥ m0. The degree of X in Pr is at most mnd.
Therefore r ≤ mnd+ n.
Birational geometry and moduli spaces of varieties of general type – p. 13
Degree versus Hilbert polynomial
Suppose that we fix the volume of KY ,
d = vol(Y,KY ) = lim supm→∞
n!H0(Y,OY (mKY ))
mn.
Fix m ≥ m0. The degree of X in Pr is at most mnd.
Therefore r ≤ mnd+ n.
In particular the family of all canonically polarisedvarieties of dimension n such that Kn
X = d is abounded family.
Birational geometry and moduli spaces of varieties of general type – p. 13
Degree versus Hilbert polynomial
Suppose that we fix the volume of KY ,
d = vol(Y,KY ) = lim supm→∞
n!H0(Y,OY (mKY ))
mn.
Fix m ≥ m0. The degree of X in Pr is at most mnd.
Therefore r ≤ mnd+ n.
In particular the family of all canonically polarisedvarieties of dimension n such that Kn
X = d is abounded family.
For this we use the Chow variety, not the Hilbertscheme.
Birational geometry and moduli spaces of varieties of general type – p. 13
Degree versus Hilbert polynomial
Suppose that we fix the volume of KY ,
d = vol(Y,KY ) = lim supm→∞
n!H0(Y,OY (mKY ))
mn.
Fix m ≥ m0. The degree of X in Pr is at most mnd.
Therefore r ≤ mnd+ n.
In particular the family of all canonically polarisedvarieties of dimension n such that Kn
X = d is abounded family.
For this we use the Chow variety, not the Hilbertscheme.
Just need to fix the degree d and the dimension n.Birational geometry and moduli spaces of varieties of general type – p. 13
Birational boundedness
It follows that the family of all smooth projectivevarieties Y of dimension n and volume d isbirationally bounded.
Birational geometry and moduli spaces of varieties of general type – p. 14
Birational boundedness
It follows that the family of all smooth projectivevarieties Y of dimension n and volume d isbirationally bounded.
We may find a family Y −→ U of varieties such thatevery smooth projective variety Y of dimension nand volume d is birational to at least one fibre.
Birational geometry and moduli spaces of varieties of general type – p. 14
Birational boundedness
It follows that the family of all smooth projectivevarieties Y of dimension n and volume d isbirationally bounded.
We may find a family Y −→ U of varieties such thatevery smooth projective variety Y of dimension nand volume d is birational to at least one fibre.
Note that in the definition of boundedness, we donot a priori require that every fibre of Y is a varietyof general type of volume d.
Birational geometry and moduli spaces of varieties of general type – p. 14
Birational boundedness
It follows that the family of all smooth projectivevarieties Y of dimension n and volume d isbirationally bounded.
We may find a family Y −→ U of varieties such thatevery smooth projective variety Y of dimension nand volume d is birational to at least one fibre.
Note that in the definition of boundedness, we donot a priori require that every fibre of Y is a varietyof general type of volume d.
Use the moduli space of canonically polarisedvarieties X (the smooth case) to give a birationalclassification of smooth projective varieties Y ofgeneral type.
Birational geometry and moduli spaces of varieties of general type – p. 14
Semi-stable reduction
An alteration is a proper generically finite surjectivemorphism V −→ U .
Birational geometry and moduli spaces of varieties of general type – p. 15
Semi-stable reduction
An alteration is a proper generically finite surjectivemorphism V −→ U .
Theorem: (Abramovich-Karu) Given a morphismY −→ U whose generic fibre is geometricallyirreducible then there is an alteration V −→ U andan alteration X −→ Y ′ of the main component Y ′ ofY ×
UV such that X −→ V has reduced fibres and X
is canonical.
Birational geometry and moduli spaces of varieties of general type – p. 15
Semi-stable reduction
An alteration is a proper generically finite surjectivemorphism V −→ U .
Theorem: (Abramovich-Karu) Given a morphismY −→ U whose generic fibre is geometricallyirreducible then there is an alteration V −→ U andan alteration X −→ Y ′ of the main component Y ′ ofY ×
UV such that X −→ V has reduced fibres and X
is canonical.
Choose V smooth and X with quotient singularities.
Birational geometry and moduli spaces of varieties of general type – p. 15
Semi-stable reduction
An alteration is a proper generically finite surjectivemorphism V −→ U .
Theorem: (Abramovich-Karu) Given a morphismY −→ U whose generic fibre is geometricallyirreducible then there is an alteration V −→ U andan alteration X −→ Y ′ of the main component Y ′ ofY ×
UV such that X −→ V has reduced fibres and X
is canonical.
Choose V smooth and X with quotient singularities.
So we may assume we have a semi-stable family ofprojective varieties which includes every variety ofdimension n and volume d.
Birational geometry and moduli spaces of varieties of general type – p. 15
Deformation invariance
By taking the closure in the Chow variety we mayassume (from the beginning) that U is projective.
Birational geometry and moduli spaces of varieties of general type – p. 16
Deformation invariance
By taking the closure in the Chow variety we mayassume (from the beginning) that U is projective.
Theorem: (Siu) If Y −→ U is a smooth projective
morphism then for all m ∈ N, h0(Xt,OXt(mKXt
))are deformation invariants, where Xt are the fibres.
Birational geometry and moduli spaces of varieties of general type – p. 16
Deformation invariance
By taking the closure in the Chow variety we mayassume (from the beginning) that U is projective.
Theorem: (Siu) If Y −→ U is a smooth projective
morphism then for all m ∈ N, h0(Xt,OXt(mKXt
))are deformation invariants, where Xt are the fibres.
So we may assume that the Hilbert polynomial isconstant.
Birational geometry and moduli spaces of varieties of general type – p. 16
Relative canonical model
Take the relative canonical model of π : Y −→ U
X = ProjU
(⊕
m∈N
π∗OY(mKY)
)−→ U.
Birational geometry and moduli spaces of varieties of general type – p. 17
Relative canonical model
Take the relative canonical model of π : Y −→ U
X = ProjU
(⊕
m∈N
π∗OY(mKY)
)−→ U.
Note that KX is ample for every fibre X = Xt.
Birational geometry and moduli spaces of varieties of general type – p. 17
Relative canonical model
Take the relative canonical model of π : Y −→ U
X = ProjU
(⊕
m∈N
π∗OY(mKY)
)−→ U.
Note that KX is ample for every fibre X = Xt.
By a result of Keel and Mori we may assume that thequotient is represented by an algebraic space M.
Birational geometry and moduli spaces of varieties of general type – p. 17
Relative canonical model
Take the relative canonical model of π : Y −→ U
X = ProjU
(⊕
m∈N
π∗OY(mKY)
)−→ U.
Note that KX is ample for every fibre X = Xt.
By a result of Keel and Mori we may assume thatthe quotient is represented by an algebraic space M.
Kollár gave a general criteria for projectivity of M.
Birational geometry and moduli spaces of varieties of general type – p. 17
Relative canonical model
Take the relative canonical model of π : Y −→ U
X = ProjU
(⊕
m∈N
π∗OY(mKY)
)−→ U.
Note that KX is ample for every fibre X = Xt.
By a result of Keel and Mori we may assume thatthe quotient is represented by an algebraic space M.
Kollár gave a general criteria for projectivity of M.
Fujino verified this criteria in this case.
Birational geometry and moduli spaces of varieties of general type – p. 17
Relative canonical model
Take the relative canonical model of π : Y −→ U
X = ProjU
(⊕
m∈N
π∗OY(mKY)
)−→ U.
Note that KX is ample for every fibre X = Xt.
By a result of Keel and Mori we may assume thatthe quotient is represented by an algebraic space M.
Kollár gave a general criteria for projectivity of M.
Fujino verified this criteria in this case.
Kovács & Patakfalvi generalised to log pairs.
Birational geometry and moduli spaces of varieties of general type – p. 17
What is missing?
We have not given the moduli space a schemestructure.
Birational geometry and moduli spaces of varieties of general type – p. 18
What is missing?
We have not given the moduli space a schemestructure.
Equivalently we have not defined a functor.
Birational geometry and moduli spaces of varieties of general type – p. 18
What is missing?
We have not given the moduli space a schemestructure.
Equivalently we have not defined a functor.
The problem is that there are families of non-normalvarieties which cannot be smoothed, so that there arecomponents of the moduli space whose generalmember corresponds to a non-normal variety.
Birational geometry and moduli spaces of varieties of general type – p. 18
What is missing?
We have not given the moduli space a schemestructure.
Equivalently we have not defined a functor.
The problem is that there are families of non-normalvarieties which cannot be smoothed, so that there arecomponents of the moduli space whose generalmember corresponds to a non-normal variety.
These components might intersect the components(the smooth case)whose general points correspondto normal varieties.
Birational geometry and moduli spaces of varieties of general type – p. 18
What is missing?
We have not given the moduli space a schemestructure.
Equivalently we have not defined a functor.
The problem is that there are families of non-normalvarieties which cannot be smoothed, so that there arecomponents of the moduli space whose generalmember corresponds to a non-normal variety.
These components might intersect the components(the smooth case)whose general points correspondto normal varieties.
We have to include all of the components if we wanta reasonable scheme structure.
Birational geometry and moduli spaces of varieties of general type – p. 18
What is missing?
We have not given the moduli space a schemestructure.
Equivalently we have not defined a functor.
The problem is that there are families of non-normalvarieties which cannot be smoothed, so that there arecomponents of the moduli space whose generalmember corresponds to a non-normal variety.
These components might intersect the components(the smooth case)whose general points correspondto normal varieties.
We have to include all of the components if we wanta reasonable scheme structure.
Then we get a reasonable deformation theory.Birational geometry and moduli spaces of varieties of general type – p. 18
Surfaces with small invariants
There has been considerable interest in constructingsmooth projective surfaces with pg = 0 and smallfundamental group.
Birational geometry and moduli spaces of varieties of general type – p. 19
Surfaces with small invariants
There has been considerable interest in constructingsmooth projective surfaces with pg = 0 and smallfundamental group.
Start with an explicit rational surface S0 withquotient singularities such that KS0
is ample and thefundamental group of the smooth locus is small.
Birational geometry and moduli spaces of varieties of general type – p. 19
Surfaces with small invariants
There has been considerable interest in constructingsmooth projective surfaces with pg = 0 and smallfundamental group.
Start with an explicit rational surface S0 withquotient singularities such that KS0
is ample and thefundamental group of the smooth locus is small.
Check that there is a smoothing S of S0 to a smoothprojective surface S such that KS is ample.
Birational geometry and moduli spaces of varieties of general type – p. 19
Surfaces with small invariants
There has been considerable interest in constructingsmooth projective surfaces with pg = 0 and smallfundamental group.
Start with an explicit rational surface S0 withquotient singularities such that KS0
is ample and thefundamental group of the smooth locus is small.
Check that there is a smoothing S of S0 to a smoothprojective surface S such that KS is ample.
Construct new Campedelli surfaces S, smooth
projective surfaces with (Y. Lee, J. Park): K2S = 0
and π1(S) ∈ {0,Z2,Z4}.
Birational geometry and moduli spaces of varieties of general type – p. 19
Surfaces with small invariants
There has been considerable interest in constructingsmooth projective surfaces with pg = 0 and smallfundamental group.
Start with an explicit rational surface S0 withquotient singularities such that KS0
is ample and thefundamental group of the smooth locus is small.
Check that there is a smoothing S of S0 to a smoothprojective surface S such that KS is ample.
Construct new Campedelli surfaces S, smooth
projective surfaces with (Y. Lee, J. Park): K2S = 0
and π1(S) ∈ {0,Z2,Z4}.
Non-trivial deformation theory, Q-Gorensteindeformation (Wahl).
Birational geometry and moduli spaces of varieties of general type – p. 19
What to parametrise?
A big hint is given by the construction we have justgiven:
Birational geometry and moduli spaces of varieties of general type – p. 20
What to parametrise?
A big hint is given by the construction we have justgiven:
• log pairs (X,∆) such that KX +∆ is ample.
Birational geometry and moduli spaces of varieties of general type – p. 20
What to parametrise?
A big hint is given by the construction we have justgiven:
• log pairs (X,∆) such that KX +∆ is ample.
We must allow non-normal singularities (considerthe case of nodal curves and what the fibres of asemi-stable reduction look like).
Birational geometry and moduli spaces of varieties of general type – p. 20
What to parametrise?
A big hint is given by the construction we have justgiven:
• log pairs (X,∆) such that KX +∆ is ample.
We must allow non-normal singularities (considerthe case of nodal curves and what the fibres of asemi-stable reduction look like).
• we work with semi log canonical pairs (X,∆).
Birational geometry and moduli spaces of varieties of general type – p. 20
What to parametrise?
A big hint is given by the construction we have justgiven:
• log pairs (X,∆) such that KX +∆ is ample.
We must allow non-normal singularities (considerthe case of nodal curves and what the fibres of asemi-stable reduction look like).
• we work with semi log canonical pairs (X,∆).
X has nodal singularities in codimension one and
the normalisation (Xν, D +∆ν) is log canonical,where D is the double locus.
Birational geometry and moduli spaces of varieties of general type – p. 20
What to parametrise?
A big hint is given by the construction we have justgiven:
• log pairs (X,∆) such that KX +∆ is ample.
We must allow non-normal singularities (considerthe case of nodal curves and what the fibres of asemi-stable reduction look like).
• we work with semi log canonical pairs (X,∆).
X has nodal singularities in codimension one and
the normalisation (Xν, D +∆ν) is log canonical,where D is the double locus.
the fibres of the relative canonical model are semilog canonical—part of the statement of adjunction.
Birational geometry and moduli spaces of varieties of general type – p. 20
Log canonical pairs (X,∆)
(X,∆) is log smooth if X is smooth and ∆ hasglobal normal crossings.
Birational geometry and moduli spaces of varieties of general type – p. 21
Log canonical pairs (X,∆)
(X,∆) is log smooth if X is smooth and ∆ hasglobal normal crossings.
A log resolution π : Y −→ X is a projective
birational map s.t. (Y,Γ = ∆̃ + E) is log smooth
and E =∑
Ei supports an ample divisor over X .
Birational geometry and moduli spaces of varieties of general type – p. 21
Log canonical pairs (X,∆)
(X,∆) is log smooth if X is smooth and ∆ hasglobal normal crossings.
A log resolution π : Y −→ X is a projective
birational map s.t. (Y,Γ = ∆̃ + E) is log smooth
and E =∑
Ei supports an ample divisor over X .
We may write
KY + Γ = π∗(KX +∆) +∑
aiEi.
Birational geometry and moduli spaces of varieties of general type – p. 21
Log canonical pairs (X,∆)
(X,∆) is log smooth if X is smooth and ∆ hasglobal normal crossings.
A log resolution π : Y −→ X is a projective
birational map s.t. (Y,Γ = ∆̃ + E) is log smooth
and E =∑
Ei supports an ample divisor over X .
We may write
KY + Γ = π∗(KX +∆) +∑
aiEi.
ai = a(Ei, X,∆) is the log discrepancy of Ei.
Birational geometry and moduli spaces of varieties of general type – p. 21
Log canonical pairs (X,∆)
(X,∆) is log smooth if X is smooth and ∆ hasglobal normal crossings.
A log resolution π : Y −→ X is a projective
birational map s.t. (Y,Γ = ∆̃ + E) is log smooth
and E =∑
Ei supports an ample divisor over X .
We may write
KY + Γ = π∗(KX +∆) +∑
aiEi.
ai = a(Ei, X,∆) is the log discrepancy of Ei.
a = infi,Y ai is the log discrepancy of (X,∆).(X,∆) is log canonical if a ≥ 0.
Birational geometry and moduli spaces of varieties of general type – p. 21
Properties of log canonical pairs
If (X,∆) is log canonical then
H0(X,OX(m(KX+∆))) = H0(Y,OY (m(KY+Γ))).
This is the essential property of log canonical pairs.
Birational geometry and moduli spaces of varieties of general type – p. 22
Properties of log canonical pairs
If (X,∆) is log canonical then
H0(X,OX(m(KX+∆))) = H0(Y,OY (m(KY+Γ))).
This is the essential property of log canonical pairs.
(X,∆) is klt if ⌊∆⌋ = 0 and a > 0.
Birational geometry and moduli spaces of varieties of general type – p. 22
Properties of log canonical pairs
If (X,∆) is log canonical then
H0(X,OX(m(KX+∆))) = H0(Y,OY (m(KY+Γ))).
This is the essential property of log canonical pairs.
(X,∆) is klt if ⌊∆⌋ = 0 and a > 0.
Kawamata log terminal pairs are well-behaved andmost of the standard results about smooth projectivevarieties extend to klt pairs.
Birational geometry and moduli spaces of varieties of general type – p. 22
Properties of log canonical pairs
If (X,∆) is log canonical then
H0(X,OX(m(KX+∆))) = H0(Y,OY (m(KY+Γ))).
This is the essential property of log canonical pairs.
(X,∆) is klt if ⌊∆⌋ = 0 and a > 0.
Kawamata log terminal pairs are well-behaved andmost of the standard results about smooth projectivevarieties extend to klt pairs.
Some of the basic results about log canonical pairsfail and we are ignorant of many of the rest.
Birational geometry and moduli spaces of varieties of general type – p. 22
Properties of log canonical pairs
If (X,∆) is log canonical then
H0(X,OX(m(KX+∆))) = H0(Y,OY (m(KY+Γ))).
This is the essential property of log canonical pairs.
(X,∆) is klt if ⌊∆⌋ = 0 and a > 0.
Kawamata log terminal pairs are well-behaved andmost of the standard results about smooth projectivevarieties extend to klt pairs.
Some of the basic results about log canonical pairsfail and we are ignorant of many of the rest.
We must work with log canonical pairs since thedouble locus always comes with coefficient one.
Birational geometry and moduli spaces of varieties of general type – p. 22