The first case of algebraic D-modules are modules over the Weyl algebra A_n(K) over a field K of characteristic zero. It is the algebra consisting of polynomials in the following variables

x₁, ..., x_n, ∂₁, ..., ∂_n.

where the variables x_i and ∂_j separately commute with each other, and x_i and ∂_j commute for i ≠ j, but the commutator satisfies the relation

[∂_i, x_i] = ∂_ix_i − x_i∂_i = 1.

For any polynomial f(x₁, ..., x_n), this implies the relation

[∂_i, f] = ∂f / ∂x_i,

thereby relating the Weyl algebra to differential equations.

An (algebraic) D-module is, by definition, a left module over the ring A_n(K). Examples for D-modules include the Weyl algebra itself (acting on itself by left multiplication), the (commutative) polynomial ring K[x₁, ..., x_n], where x_i acts by multiplication and ∂_j acts by partial differentiation with respect to x_j and, in a similar vein, the ring ${\displaystyle {\mathcal {O}}(\mathbf {C} ^{n})}$  of holomorphic functions on Cⁿ (functions of n complex variables.)

Given some differential operator P = a_n(x) ∂ⁿ + ... + a₁(x) ∂¹ + a₀(x), where x is a complex variable, a_i(x) are polynomials, the quotient module M = A₁(C)/A₁(C)P is closely linked to space of solutions of the differential equation

P f = 0,

where f is some holomorphic function in C, say. The vector space consisting of the solutions of that equation is given by the space of homomorphisms of D-modules ${\displaystyle \mathrm {Hom} (M,{\mathcal {O}}(\mathbf {C} ))}$ .

The general theory of D-modules is developed on a smooth algebraic variety X defined over an algebraically closed field K of characteristic zero, such as K = C. The sheaf of differential operators D_X is defined to be the O_X-algebra generated by the vector fields on X, interpreted as derivations. A (left) D_X-module M is an O_X-module with a left action of D_X on it. Giving such an action is equivalent to specifying a K-linear map

${\displaystyle \nabla :D_{X}\rightarrow \operatorname {End} _{K}(M),v\mapsto \nabla _{v}}$ 

satisfying

${\displaystyle \nabla _{fv}(m)=f\,\nabla _{v}(m)}$ 

${\displaystyle \nabla _{v}(fm)=v(f)m+f\,\nabla _{v}(m)}$  (Leibniz rule)

${\displaystyle \nabla _{[v,w]}(m)=[\nabla _{v},\nabla _{w}](m)}$ 

Here f is a regular function on X, v and w are vector fields, m a local section of M, [−, −] denotes the commutator. Therefore, if M is in addition a locally free O_X-module, giving M a D-module structure is nothing else than equipping the vector bundle associated to M with a flat (or integrable) connection.

As the ring D_X is noncommutative, left and right D-modules have to be distinguished. However, the two notions can be exchanged, since there is an equivalence of categories between both types of modules, given by mapping a left module M to the tensor product M ⊗ Ω_X, where Ω_X is the line bundle given by the highest exterior power of differential 1-forms on X. This bundle has a natural right action determined by

ω ⋅ v := − Lie_v (ω),

where v is a differential operator of order one, that is to say a vector field, ω a n-form (n = dim X), and Lie denotes the Lie derivative.

Locally, after choosing some system of coordinates x₁, ..., x_n (n = dim X) on X, which determine a basis ∂₁, ..., ∂_n of the tangent space of X, sections of D_X can be uniquely represented as expressions

${\displaystyle \sum f_{i_{1},\dots ,i_{n}}\partial _{1}^{i_{1}}\cdots \partial _{n}^{i_{n}}}$ , where the ${\displaystyle f_{i_{1},\dots ,i_{n}}}$  are regular functions on X.

In particular, when X is the n-dimensional affine space, this D_X is the Weyl algebra in n variables.

Many basic properties of D-modules are local and parallel the situation of coherent sheaves. This builds on the fact that D_X is a locally free sheaf of O_X-modules, albeit of infinite rank, as the above-mentioned O_X-basis shows. A D_X-module that is coherent as an O_X-module can be shown to be necessarily locally free (of finite rank).

Functoriality edit

D-modules on different algebraic varieties are connected by pullback and pushforward functors comparable to the ones for coherent sheaves. For a map f: X → Y of smooth varieties, the definitions are this:

D_X→Y := O_X ⊗_f⁻¹(OY) f⁻¹(D_Y)

This is equipped with a left D_X action in a way that emulates the chain rule, and with the natural right action of f⁻¹(D_Y). The pullback is defined as

f^∗(M) := D_X→Y ⊗_f⁻¹(DY) f⁻¹(M).

Here M is a left D_Y-module, while its pullback is a left module over X. This functor is right exact, its left derived functor is denoted Lf^∗. Conversely, for a right D_X-module N,

f_∗(N) := f_∗(N ⊗_DXD_X→Y)

is a right D_Y-module. Since this mixes the right exact tensor product with the left exact pushforward, it is common to set instead

f_∗(N) := Rf_∗(N ⊗^L_DXD_X→Y).

Because of this, much of the theory of D-modules is developed using the full power of homological algebra, in particular derived categories.

Holonomic modules over the Weyl algebra edit

It can be shown that the Weyl algebra is a (left and right) Noetherian ring. Moreover, it is simple, that is to say, its only two-sided ideal are the zero ideal and the whole ring. These properties make the study of D-modules manageable. Notably, standard notions from commutative algebra such as Hilbert polynomial, multiplicity and length of modules carry over to D-modules. More precisely, D_X is equipped with the Bernstein filtration, that is, the filtration such that F^pA_n(K) consists of K-linear combinations of differential operators x^α∂^β with |α| + |β| ≤ p (using multiindex notation). The associated graded ring is seen to be isomorphic to the polynomial ring in 2n indeterminates. In particular it is commutative.

Finitely generated D-modules M are endowed with so-called "good" filtrations F^∗M, which are ones compatible with F^∗A_n(K), essentially parallel to the situation of the Artin–Rees lemma. The Hilbert polynomial is defined to be the numerical polynomial that agrees with the function

n ↦ dim_K FⁿM

for large n. The dimension d(M) of an A_n(K)-module M is defined to be the degree of the Hilbert polynomial. It is bounded by the Bernstein inequality

n ≤ d(M) ≤ 2n.

A module whose dimension attains the least possible value, n, is called holonomic.

The A₁(K)-module M = A₁(K)/A₁(K)P (see above) is holonomic for any nonzero differential operator P, but a similar claim for higher-dimensional Weyl algebras does not hold.

General definition edit

As mentioned above, modules over the Weyl algebra correspond to D-modules on affine space. The Bernstein filtration not being available on D_X for general varieties X, the definition is generalized to arbitrary affine smooth varieties X by means of order filtration on D_X, defined by the order of differential operators. The associated graded ring gr D_X is given by regular functions on the cotangent bundle T^∗X.

The characteristic variety is defined to be the subvariety of the cotangent bundle cut out by the radical of the annihilator of gr M, where again M is equipped with a suitable filtration (with respect to the order filtration on D_X). As usual, the affine construction then glues to arbitrary varieties.

The Bernstein inequality continues to hold for any (smooth) variety X. While the upper bound is an immediate consequence of the above interpretation of gr D_X in terms of the cotangent bundle, the lower bound is more subtle.

Properties and characterizations edit

Holonomic modules have a tendency to behave like finite-dimensional vector spaces. For example, their length is finite. Also, M is holonomic if and only if all cohomology groups of the complex Li^∗(M) are finite-dimensional K-vector spaces, where i is the closed immersion of any point of X.

For any D-module M, the dual module is defined by

${\displaystyle \mathrm {D} (M):={\mathcal {R}}\operatorname {Hom} (M,D_{X})\otimes \Omega _{X}^{-1}[\dim X].}$ 

Holonomic modules can also be characterized by a homological condition: M is holonomic if and only if D(M) is concentrated (seen as an object in the derived category of D-modules) in degree 0. This fact is a first glimpse of Verdier duality and the Riemann–Hilbert correspondence. It is proven by extending the homological study of regular rings (especially what is related to global homological dimension) to the filtered ring D_X.

Another characterization of holonomic modules is via symplectic geometry. The characteristic variety Ch(M) of any D-module M is, seen as a subvariety of the cotangent bundle T^∗X of X, an involutive variety. The module is holonomic if and only if Ch(M) is Lagrangian.

One of the early applications of holonomic D-modules was the Bernstein–Sato polynomial.

Kazhdan–Lusztig conjecture edit

The Kazhdan–Lusztig conjecture was proved using D-modules.

Riemann–Hilbert correspondence edit

The Riemann–Hilbert correspondence establishes a link between certain D-modules and constructible sheaves. As such, it provided a motivation for introducing perverse sheaves.

Geometric representation theory edit

D-modules are also applied in geometric representation theory. A main result in this area is the Beilinson–Bernstein localization. It relates D-modules on flag varieties G/B to representations of the Lie algebra ${\displaystyle {\mathfrak {g}}}$  of a reductive group G. D-modules are also crucial in the formulation of the geometric Langlands program.

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