Derived noncommutative algebraic geometry explained

In mathematics, derived noncommutative algebraic geometry,^[1] the derived version of noncommutative algebraic geometry, is the geometric study of derived categories and related constructions of triangulated categories using categorical tools. Some basic examples include the bounded derived category of coherent sheaves on a smooth variety,

D^b(X)

, called its derived category, or the derived category of perfect complexes on an algebraic variety, denoted

D_{\operatorname{perf}

}(X). For instance, the derived category of coherent sheaves

D^b(X)

on a smooth projective variety can be used as an invariant of the underlying variety for many cases (if

has an ample (anti-)canonical sheaf). Unfortunately, studying derived categories as geometric objects of themselves does not have a standardized name.

Derived category of projective line

The derived category of

P¹

is one of the motivating examples for derived non-commutative schemes due to its easy categorical structure. Recall that the Euler sequence of

P¹

is the short exact sequence

0\tol{O}(-2)\tol{O}(-1)^⊕\tol{O}\to0

if we consider the two terms on the right as a complex, then we get the distinguished triangle

l{O}(-1)^⊕\overset{\phi}{ → }l{O}\to\operatorname{Cone}(\phi)\overset{+1}{ → }.

Since

\operatorname{Cone}(\phi)\congl{O}(-2)[+1]

we have constructed this sheaf

l{O}(-2)

using only categorical tools. We could repeat this again by tensoring the Euler sequence by the flat sheaf

l{O}(-1)

, and apply the cone construction again. If we take the duals of the sheaves, then we can construct all of the line bundles in

\operatorname{Coh}(P¹⁾

using only its triangulated structure. It turns out the correct way of studying derived categories from its objects and triangulated structure is with exceptional collections.

Semiorthogonal decompositions and exceptional collections

See main article: semiorthogonal decomposition. The technical tools for encoding this construction are semiorthogonal decompositions and exceptional collections.^[2] A semiorthogonal decomposition of a triangulated category

l{T}

is a collection of full triangulated subcategories

l{T}_1,\ldots,l{T}_n

such that the following two properties hold

(1) For objects

T_i\in\operatorname{Ob}(l{T}_i)

we have

\operatorname{Hom}(T_i,T_j)=0

for

i>j

(2) The subcategories

l{T}_i

generate

l{T}

, meaning every object

T\in\operatorname{Ob}(l{T})

can be decomposed in to a sequence of

T_i\in\operatorname{Ob}(l{T})

0=T_n\toT_n-1\to … \toT₁\toT₀=T

such that

\operatorname{Cone}(T_i\toT_i-1)\in\operatorname{Ob}(l{T}_i)

. Notice this is analogous to a filtration of an object in an abelian category such that the cokernels live in a specific subcategory.

We can specialize this a little further by considering exceptional collections of objects, which generate their own subcategories. An object

in a triangulated category is called exceptional if the following property holds

\operatorname{Hom}(E,E[+\ell])=\begin{cases} k&if\ell=0\\ 0&if\ell ≠ 0 \end{cases}

where

is the underlying field of the vector space of morphisms. A collection of exceptional objects

E_1,\ldots,E_r

is an exceptional collection of length

if for any

i>j

and any

\ell

, we have

\operatorname{Hom}(E_i,E_j[+\ell])=0

and is a strong exceptional collection if in addition, for any

\ell ≠ 0

and any

i,j

, we have

\operatorname{Hom}(E_i,E_j[+\ell])=0

We can then decompose our triangulated category into the semiorthogonal decomposition

l{T}=\langlel{T}',E_1,\ldots,E_r\rangle

where

l{T}'=\langleE_1,\ldots,E_r\rangle^\perp

, the subcategory of objects in

E\in\operatorname{Ob}(l{T})

such that

\operatorname{Hom}(E,E_i[+\ell])=0

. If in addition

l{T}'=0

then the strong exceptional collection is called full.

Beilinson's theorem

Beilinson provided the first example of a full strong exceptional collection. In the derived category

D^b(Pⁿ⁾

the line bundles

l{O}(-n),l{O}(-n+1),\ldots,l{O}(-1),l{O}

form a full strong exceptional collection. He proves the theorem in two parts. First showing these objects are an exceptional collection and second by showing the diagonal

l{O}_\Delta

Pⁿ x Pⁿ

has a resolution whose compositions are tensors of the pullback of the exceptional objects.

Technical Lemma

An exceptional collection of sheaves

E_1,E_2,\ldots,E_r

is full if there exists a resolution

0\to

	*E
p
	1

⊗

	*F
p
	1

\to … \to

	*E
p
	n

⊗

	*F
p
	n

\tol{O}_\Delta\to0

D^{b(X x}X)

where

F_i

are arbitrary coherent sheaves on

Another way to reformulate this lemma for

X=Pⁿ

is by looking at the Koszul complex associated to

n
oplus
i=0

l{O}(-D_i)\xrightarrow{\phi}l{O}

where

D_i

are hyperplane divisors of

Pⁿ

. This gives the exact complex

0\to

n
l{O}\left(-\sum
i=1

D_i\right)\to … \to oplus_il{O}(-D_i-D_j)

nl{O}(-D
\to oplus
i)

\tol{O}\to0

which gives a way to construct

l{O}(-n-1)

using the sheaves

l{O}(-n),\ldots,l{O}(-1),l{O}

, since they are the sheaves used in all terms in the above exact sequence, except for

	n
l{O}\left(-\sum
	i=0

D_i\right)\congl{O}(-n-1)

which gives a derived equivalence of the rest of the terms of the above complex with

l{O}(-n-1)

. For

n=2

the Koszul complex above is the exact complex

0\tol{O}(-3)\tol{O}(-2) ⊕ l{O}(-2)\tol{O}(-1) ⊕ l{O}(-1)\tol{O}\to0

giving the quasi isomorphism of

l{O}(-3)

with the complex

0\tol{O}(-2) ⊕ l{O}(-2)\tol{O}(-1) ⊕ l{O}(-1)\tol{O}\to0

Orlov's reconstruction theorem

is a smooth projective variety with ample (anti-)canonical sheaf and there is an equivalence of derived categories

F:D^b(X)\toD^b(Y)

, then there is an isomorphism of the underlying varieties.^[3]

Sketch of proof

The proof starts out by analyzing two induced Serre functors on

D^b(Y)

and finding an isomorphism between them. It particular, it shows there is an object

\omega_Y=F(\omega_X)

which acts like the dualizing sheaf on

. The isomorphism between these two functors gives an isomorphism of the set of underlying points of the derived categories. Then, what needs to be check is an ismorphism

	⊗ k
F(\omega
	X

)\cong

	⊗ k
\omega
	Y

, for any

k\inN

, giving an isomorphism of canonical rings

A(X)=

	infty
oplus
	k=0

	⊗ k
H
	X

)\cong

	infty
oplus
	k=0

	⊗ k
H
	Y

)

\omega_Y

can be shown to be (anti-)ample, then the proj of these rings will give an isomorphism

X\toY

. All of the details are contained in Dolgachev's notes.

Failure of reconstruction

This theorem fails in the case

is Calabi-Yau, since

\omega_X\congl{O}_X

, or is the product of a variety which is Calabi-Yau. Abelian varieties are a class of examples where a reconstruction theorem could never hold. If

is an abelian variety and

\hat{X}

is its dual, the Fourier–Mukai transform with kernel

l{P}

, the Poincare bundle,^[4] gives an equivalence

FM_l{P

}:D^b(X) \to D^b(\hat)of derived categories. Since an abelian variety is generally not isomorphic to its dual, there are derived equivalent derived categories without isomorphic underlying varieties.^[5] There is an alternative theory of tensor triangulated geometry where we consider not only a triangulated category, but also a monoidal structure, i.e. a tensor product. This geometry has a full reconstruction theorem using the spectrum of categories.^[6]

Equivalences on K3 surfaces

K3 surfaces are another class of examples where reconstruction fails due to their Calabi-Yau property. There is a criterion for determining whether or not two K3 surfaces are derived equivalent: the derived category of the K3 surface

D^b(X)

is derived equivalent to another K3

D^b(Y)

if and only if there is a Hodge isometry

H^2(X,Z)\toH^2(Y,Z)

, that is, an isomorphism of Hodge structure. Moreover, this theorem is reflected in the motivic world as well, where the Chow motives are isomorphic if and only if there is an isometry of Hodge structures.^[7]

Autoequivalences

One nice application of the proof of this theorem is the identification of autoequivalences of the derived category of a smooth projective variety with ample (anti-)canonical sheaf. This is given by

\operatorname{Auteq}(D^b(X))\cong(\operatorname{Pic}(X)\rtimes\operatorname{Aut}(X)) x Z

Where an autoequivalence

is given by an automorphism

f:X\toX

, then tensored by a line bundle

l{L}\in\operatorname{Pic}(X)

and finally composed with a shift. Note that

\operatorname{Aut}(X)

acts on

\operatorname{Pic}(X)

via the polarization map,

g\mapstog^{*(L) ⊗}L^-1

.^[8]

Relation with motives

The bounded derived category

D^b(X)

was used extensively in SGA6 to construct an intersection theory with

K(X)

and

Gr_\gammaK(X) ⊗ Q

. Since these objects are intimately relative with the Chow ring of

, its chow motive, Orlov asked the following question: given a fully-faithful functor

F:D^b(X)\toD^b(Y)

is there an induced map on the chow motives

f:M(X)\toM(Y)

such that

M(X)

is a summand of

M(Y)

?^[9] In the case of K3 surfaces, a similar result has been confirmed since derived equivalent K3 surfaces have an isometry of Hodge structures, which gives an isomorphism of motives.

Derived category of singularities

On a smooth variety there is an equivalence between the derived category

D^b(X)

and the thick^[10] ^[11] full triangulated

D_{\operatorname{perf}

}(X) of perfect complexes. For separated, Noetherian schemes of finite Krull dimension (called the ELF condition)^[12] this is not the case, and Orlov defines the derived category of singularities as their difference using a quotient of categories. For an ELF scheme

its derived category of singularities is defined as

D_sg(X):=

	b(X)/D
D
	perf(X)

^[13]

for a suitable definition of localization of triangulated categories.

Construction of localization

Although localization of categories is defined for a class of morphisms

\Sigma

in the category closed under composition, we can construct such a class from a triangulated subcategory. Given a full triangulated subcategory

l{N}\subsetl{T}

the class of morphisms

\Sigma(l{N})

l{T}

where

fits into a distinguished triangle

X\xrightarrow{s}Y\toN\toX[+1]

with

X,Y\inl{T}

and

N\inl{N}

. It can be checked this forms a multiplicative system using the octahedral axiom for distinguished triangles. Given

X\xrightarrow{s}Y\xrightarrow{s'}Z

with distinguished triangles

X\xrightarrow{s}Y\toN\toX[+1]

Y\xrightarrow{s'}Z\toN'\toY[+1]

where

N,N'\inl{N}

, then there are distinguished triangles

X\toZ\toM\toX[+1]

N\toM\toN'\toN[+1]

where

M\inl{N}

since

l{N}

is closed under extensions. This new category has the following properties

It is canonically triangulated where a triangle in

l{T}/l{N}

is distinguished if it is isomorphic to the image of a triangle in

l{T}

The category

l{T}/l{N}

has the following universal property: any exact functor

F:l{T}\tol{T}'

where

F(N)\cong0

where

N\inl{N}

, then it factors uniquely through the quotient functor

Q:l{T}\tol{T}/l{N}

, so there exists a morphism

\tilde{F}:l{T}/l{N}\tol{T}'

such that

\tilde{F}\circQ\simeqF

Properties of singularity category

is a regular scheme, then every bounded complex of coherent sheaves is perfect. Hence the singularity category is trivial

Any coherent sheaf

l{F}

which has support away from

\operatorname{Sing}(X)

is perfect. Hence nontrivial coherent sheaves in

D_sg(X)

have support on

\operatorname{Sing}(X)

In particular, objects in

D_sg(X)

are isomorphic to

l{F}[+k]

for some coherent sheaf

l{F}

Landau–Ginzburg models

Kontsevich proposed a model for Landau–Ginzburg models which was worked out to the following definition:^[14] a Landau–Ginzburg model is a smooth variety

together with a morphism

W:X\toA¹

which is flat. There are three associated categories which can be used to analyze the D-branes in a Landau–Ginzburg model using matrix factorizations from commutative algebra.

Associated categories

With this definition, there are three categories which can be associated to any point

w₀\inA¹

, a

Z/2

-graded category

DG
	w₀

(W)

, an exact category

\operatorname{Pair}
	w₀

(W)

, and a triangulated category

DB
	w₀

(W)

, each of which has objects

\overline{P}=(p_1:P₁\toP_0,p_0:P₀\toP₁₎

where

p_0\circp_1,p_1\circp₀

are multiplication by

W-w₀

There is also a shift functor

[+1]

send

\overline{P}

\overline{P}[+1]=(-p_0:P₀\toP_1,-p_1:P₁\toP₀₎

.

The difference between these categories are their definition of morphisms. The most general of which is

DG
	w₀

(W)

whose morphisms are the

Z/2

-graded complex

\operatorname{Hom}(\overline{P},\overline{Q})=oplus_i,j\operatorname{Hom}(P_i,Q_j)

where the grading is given by

(i-j)\bmod2

and differential acting on degree

homogeneous elements by

Df=q\circf-(-1)^df\circp

\operatorname{Pair}
	w₀

(W)

the morphisms are the degree

morphisms in

DG
	w₀

(W)

. Finally,

DB
	w₀

(W)

has the morphisms in

\operatorname{Pair}
	w₀

(W)

modulo the null-homotopies. Furthermore,

DB
	w₀

(W)

can be endowed with a triangulated structure through a graded cone-construction in

\operatorname{Pair}
	w₀

(W)

. Given

\overline{f}:\overline{P}\to\overline{Q}

there is a mapping code

C(f)

with maps

c_1:Q_{1 ⊕}P₀\toQ_{0 ⊕}P₁

where

c₁=\begin{bmatrix}q₀&f₁\ 0&-p_{1\end{bmatrix}}

and

c_0:Q_{0 ⊕}P₁\toQ_{1 ⊕}P₀

where

{\displaystylec₀={\begin{bmatrix}q₁&f₀\\0&-p₀\end{bmatrix}}}

Then, a diagram

\overline{P}\to\overline{Q}\to\overline{R}\to\overline{P}[+1]

DB
	w₀

(W)

is a distinguished triangle if it is isomorphic to a cone from

\operatorname{Pair}
	w₀

(W)

D-brane category

Using the construction of

DB
	w₀

(W)

we can define the category of D-branes of type B on

with superpotential

as the product category

DB(W)=

\prod
	w\inA₁

DB
	w₀

(W).

This is related to the singularity category as follows: Given a superpotential

with isolated singularities only at

, denote

X₀=W^-1(0)

. Then, there is an exact equivalence of categories

DB
	w₀

(W)\congD_sg(X₀₎

given by a functor induced from cokernel functor

\operatorname{Cok}

sending a pair

\overline{P}\mapsto\operatorname{Coker}(p₁₎

. In particular, since

is regular, Bertini's theorem shows

DB(W)

is only a finite product of categories.

Computational tools

Knörrer periodicity

There is a Fourier-Mukai transform

\Phi_Z

on the derived categories of two related varieties giving an equivalence of their singularity categories. This equivalence is called Knörrer periodicity. This can be constructed as follows: given a flat morphism

f:X\toA¹

from a separated regular Noetherian scheme of finite Krull dimension, there is an associated scheme

Y=X x A²

and morphism

g:Y\toA¹

such that

g=f+xy

where

are the coordinates of the

A²

-factor. Consider the fibers

X₀=f^-1(0)

Y₀=g^-1(0)

, and the induced morphism

x:Y₀\toA¹

. And the fiber

Z=x^-1(0)

. Then, there is an injection

i:Z\toY₀

and a projection

q:Z\toX₀

forming an

A¹

-bundle. The Fourier-Mukai transform

\Phi_{Z( ⋅ )}=

	*( ⋅ )
Ri
	*q

induces an equivalence of categories

D_sg(X₀₎\toD_sg(Y₀₎

called Knörrer periodicity. There is another form of this periodicity where

is replaced by the polynomial

x²+y²

.^[15] ^[16] These periodicity theorems are the main computational techniques because it allows for a reduction in the analysis of the singularity categories.

Computations

If we take the Landau–Ginzburg model

(C^2k+1,W)

where

	n
z
	0

	2
z
	1

+ … +

	2
z
	2k

, then the only fiber singular fiber of

is the origin. Then, the D-brane category of the Landau–Ginzburg model is equivalent to the singularity category

	n)))
D
	sing(\operatorname{Spec}(C[z]/(z

. Over the algebra

A=C[z]/(zⁿ⁾

there are indecomposable objects

V_i=\operatorname{Coker}(A\xrightarrow{z^i}A)=A/zⁱ

whose morphisms can be completely understood. For any pair

i,j

there are morphisms

	i:
\alpha
	j

V_i\toV_j

where

i\geqj

these are the natural projections

i<j

these are multiplication by

z^j-i

where every other morphism is a composition and linear combination of these morphisms. There are many other cases which can be explicitly computed, using the table of singularities found in Knörrer's original paper.

References

Research articles

A noncommutative version of Beilinson's theorem
Derived Categories of Toric Varieties
Derived Categories of Toric Varieties II

Notes and References

0710.1937. 10.1112/plms/pds034. Hirzebruch-Riemann-Roch-type formula for DG algebras. 2013. Shklyarov. D.. Proceedings of the London Mathematical Society. 106. 1–32. 5541558. The reference notes that the name "derived noncommutative algebraic geometry" may not be standard. Some authors (e.g., Orlov. Dmitri. October 2018. Derived noncommutative schemes, geometric realizations, and finite dimensional algebras. 1808.02287. Russian Mathematical Surveys. 73. 5. 865–918. 10.1070/RM9844. 2018RuMaS..73..865O. 119173796. 0036-0279.) describe this field as the study of derived noncommutative schemes.
Book: Liu, Yijia. Superschool on Derived Categories. 35, 37, 38, 41. Semi-orthogonal Decompositions of Derived Categories.
Book: Dolgachev, Igor. Derived categories. 105–112.
The poincare bundle
l{P}

on
X x \hat{X}

is a line bundle which is trivial on
\{0\} x \hat{X}

and
X x \{0\}

and has the property
l{P}|_{X x \{x\}

} is the line bundle represented by the point
x\in\hat{X}

.
Mukai. Shigeru. 1981. Duality between D(X) and D(X^) with its application to Picard sheaves. Nagoya Math. J.. 81. 153–175. Project Euclid. 10.1017/S002776300001922X. free.
Tensor triangulated geometry. Balmer. Paul. 2010. Proceedings of the International Congress of Mathematicians.
1705.04063. Motives of isogenous K3 surfaces. Huybrechts. Daniel. 2018. math.AG.
Web site: Notes on Automorphism Groups of Projective Varieties. Brion. Michel. 8. live. https://web.archive.org/web/20200213231444/https://www-fourier.ujf-grenoble.fr/~mbrion/autos.pdf. 13 February 2020.
math/0512620. Derived categories of coherent sheaves and motives. Orlov. Dmitri. Russian Mathematical Surveys. 60. 6. 1242–1244. 2011. 10.1070/RM2005v060n06ABEH004292. 11484447.
Meaning it is closed under extensions. Given any two objects
l{E}',l{E}''

in the subcategory, any object
l{E}

fitting into an exact sequence
0\tol{E}'\tol{E}\tol{E}''\to0

is also in the subcategory. In the triangulated case, this translates to the same conditions, but instead of an exact sequence, it is a distinguished triangle
l{E}'\tol{E}\tol{E}''\tol{E}[+1]
Web site: Higher Algebraic K-Theory of Schemes and of Derived Categories. Thomason. R.W.. Trobaugh. Thomas. live. https://web.archive.org/web/20190130235347/https://www.gwern.net/docs/math/1990-thomason.pdf. 30 January 2019.
Which he uses because of its nice properties: in particular every bounded complex of coherent sheaves
C^\bullet

has a resolution from a bounded above complex
P^\bullet\xrightarrow{\simeq}C^\bullet

such that
P^\bullet

is a complex of locally free sheaves of finite type.
Triangulated Categories of Singularities and D-Branes in Landau–Ginzburg Models. Orlov. Dmitri. math/0302304. 2003.
Kapustin. Anton. Li. Yi. 2003-12-03. D-Branes in Landau–Ginzburg Models and Algebraic Geometry. hep-th/0210296. Journal of High Energy Physics. 2003. 12. 005. 10.1088/1126-6708/2003/12/005. 2003JHEP...12..005K. 11337046. 1029-8479.
Brown. Michael K.. Dyckerhoff. Tobias. 2019-09-15. Topological K-theory of Equivariant Singularity Categories. 1611.01931. 11. math.AG.
Web site: https://gdz.sub.uni-goettingen.de/id/PPN356556735_0088?tify={%22pages%22:[159,%22panX%22:0.538,%22panY%22:0.719,%22view%22:%22info%22,%22zoom%22:0.583} Cohen-Macaulay modules on hypersurface singularities I]. Knörrer. Horst.

Derived noncommutative algebraic geometry explained

Derived category of projective line

Semiorthogonal decompositions and exceptional collections

Beilinson's theorem

Orlov's reconstruction theorem

Sketch of proof

Failure of reconstruction

Equivalences on K3 surfaces

Autoequivalences

Relation with motives

Derived category of singularities

Construction of localization

Properties of singularity category

Landau–Ginzburg models

Associated categories

D-brane category

Computational tools

Knörrer periodicity

Computations

See also

References

Research articles

Notes and References