Contents

Idea

The Fourier-Mukai transform is a categorified integral transform roughly similar to the standard Fourier transform.

Generally, for $X,Y$ two suitably well-behaved schemes (e.g. affine, smooth, complex) and with $D(X)$, $D(Y)$ their derived categories of quasicoherent sheaves, then a Fourier-Mukai transform with integral kernel $E \in D(X\times Y)$ is a functor (of triangulated categories/stable (infinity,1)-categories)

which is given as the composite of the (derived) operations of

1. pull (inverse image) along the projection $p_X\colon X\times Y \to X$

2. tensor product with $E$;

3. push (direct image) along the other projection $p_Y \colon X\times Y \to Y$

i.e.

(where here we implicitly understand all operations as derived functors). (e.g. Huybrechts 08, page 4)

Hence this is a pull-tensor-push integral transform through the product correspondence

with twist $E$ on the correspondence space.

Such concept of integral transform is rather general and may be considered also in derived algebraic geometry (e.g. BenZvi-Nadler-Preygel 13) and lots of other contexts.

As discussed at integral transforms on sheaves this kind of integral transform is a categorification of an integral transform/matrix multiplication of functions induced by an integral kernel, the role of which here is played by $E\in D(X \times Y)$.

Indeed, the central kind of result of the theory (theorem ) says that every suitable linear functor $D(X)\to D(Y)$ arises as a Fourier-Mukai transform for some $E$, a statement which is the categorification of the standard fact from linear algebra that every linear function between finite dimensional vector spaces is represented by a matrix.

The original Fourier-Mukai transform proper is the special case of the above where $X$ is an abelian variety, $Y = X^\vee$ its dual abelian variety and $E$ is the corresponding Poincaré line bundle.

If $X$ is a moduli space of line bundles over a suitable algebraic curve, then a slight variant of the Fourier-Mukai transform is the geometric Langlands correspondence in the abelian case (Frenkel 05, section 4.4, 4.5).

Definition

Let $X$ and $Y$ be schemes over a field $K$. Let $E \in D(QCoh(O_{X \times Y}))$ be an object in the derived category of quasi-coherent sheaves over their product. (This is a correspondence between $X$ and $Y$ equipped with a chain complex $E$ of quasi-coherent sheaves).

The functor $\Phi(E) : D(QCoh(O_X)) \to D(QCoh(O_Y))$ defined by

where $p$ and $q$ are the projections from $X \times Y$ onto $X$ and $Y$, respectively, is called the Fourier-Mukai transform of $E$, or the Fourier-Mukai functor induced by $E$.

When $F : D(QCoh(O_X)) \to D(QCoh(O_Y))$ is isomorphic to $\Phi(E)$ for some $E \in D(QCoh(O_{X \times Y}))$, one also says that $F$ is represented by $E$ or simply that $F$ is of Fourier-Mukai type.

Properties

The key fact is as follows

See Orlov 2003, 3.2.1 for a proof.

Enhancements

For any quasi-compact quasi-separated $k$-schemes $X$ and $Y$ there is a canonical equivalence of stable (∞,1)-categories

Related concepts

• triangulated categories of sheaves

• Grothendieck duality

References

General

• Shigeru Mukai, Duality between $D(X)$ and $D(\hat X)$ with its application to Picard sheaves. Nagoya Mathematical Journal 81: 153–175. (1981)

• Alexei Bondal, Michel van den Bergh. Generators and representability of functors in commutative and noncommutative geometry, 2002, arXiv

• Dmitri Orlov, Derived categories of coherent sheaves and equivalences between them, Russian Math. Surveys, 58 (2003), 3, 89-172, translation.

• Lutz Hille, Michel van den Bergh, Fourier-Mukai transforms (arXiv:0402043)

• Daniel Huybrechts, Fourier-Mukai transforms (2008) [pdf, pdf]

• Claudio Bartocci, Ugo Bruzzo, Daniel Hernandez Ruiperez: Fourier-Mukai and Nahm transforms in geometry and mathematical physics, Progress in Mathematics 276, Birkhäuser (2009) [doi:10.1007/b11801]

• Alice Rizzardo, Michel Van den Bergh, An example of a non-Fourier-Mukai functor between derived categories of coherent sheaves (arXiv:1410.4039)

• Pieter Belmans, section 2.2 of Grothendieck duality: lecture 3, 2014 (pdf)

Banerjee and Hudson have defined Fourier-Mukai functors analogously on algebraic cobordism.

• Anandam Banerjee, Thomas Hudson, Fourier-Mukai transformation on algebraic cobordism, pdf.

Discussion of internal homs of dg-categories in terms of refined Fourier-Mukai transforms is in

• Bertrand Toën, The homotopy theory of dg-categories and derived Morita theory, Invent. Math. 167 (2007), 615–667

• Alberto Canonaco, Paolo Stellari, Internal Homs via extensions of dg functors (arXiv:1312.5619)

Discussion in the context of geometric Langlands duality is in

• Edward Frenkel, Lectures on the Langlands Program and Conformal Field Theory (arXiv:hep-th/0512172)

For a discussion of Fourier-Mukai transforms in the setting of $(\infty,1)$-enhancements, see

• David Ben-Zvi, David Nadler, Anatoly Preygel. Integral transforms for coherent sheaves, arXiv:1312.7164

For T-duality

Discussion of the effect of T-duality on RR-field flux densities (in ordinary cohomology or in topological K-theory) as a Fourier-Mukai-like transform goes back to:

• Kentaro Hori, Yaron Oz, Section 3.1 of: F-Theory, T-Duality on K3 Surfaces and $N=2$ Supersymmetric Gauge Theories in Four Dimensions, Nucl. Phys. B 501 (1997) 97-108 [arXiv:hep-th/9702173, doi:10.1016/S0550-3213(97)00361-1]

• Kentaro Hori: (1.1) and pp. 13 of: D-branes, T-duality, and Index Theory, Adv. Theor. Math. Phys. 3 2 (1999) 281-342 [arXiv:hep-th/9902102, doi:10.4310/ATMP.1999.v3.n2.a5, journal:pdf]

  (whence “Hori’s formula”)

with explicit formulation in the context if topological T-duality:

• Peter Bouwknegt, Jarah Evslin, Varghese Mathai, (1.9) in: T-Duality: Topology Change from H-flux, Commun. Math. Phys. 249 (2004) 383-415 [hep-th/0306062, doi:10.1007/s00220-004-1115-6]

Survery and Review:

• Martin Ruderer, Fourier-Mukai Transforms from T-Duality, PhD thesis, Regensburg (2015) [urn:nbn:de:bvb:355-epub-314033, pdf]

• Bjorn Andreas, Daniel Hernandez Ruiperez: Fourier Mukai Transforms and Applications to String Theory, Rev. R. Acad. Cienc. Exactas Fis. Nat. Ser. A Mat 99 1 (2005) 29-77 [arXiv:math/0412328, spire:667425, journal: pdf]

For non-abelian T-duality:

• Eva Gevorgyan, Gor Sarkissian: Defects, Non-abelian T-duality, and the Fourier-Mukai transform of the Ramond-Ramond fields, J. High Energ. Phys. 2014 35 (2014) [doi:10.1007/JHEP03(2014)035, arXiv:1310.1264]

On superspace:

• Domenico Fiorenza, Hisham Sati, Urs Schreiber: Prop. 6.4 in: T-Duality from super Lie n-algebra cocycles for super p-branes, Adv. Theor. Math. Phys 22 5 (2018) [arXiv:1611.06536, doi:10.4310/ATMP.2018.v22.n5.a3]

For spherical T-duality:

• Peter Bouwknegt, Jarah Evslin, Varghese Mathai: Spherical T-duality and the spherical Fourier–Mukai transform, Journal of Geometry and Physics 133 (2018) 303-314 [doi:10.1016/j.geomphys.2018.07.020, arXiv:1502.04444]