nLab Kähler C^∞-differentials of smooth functions are differential 1-forms

Idea

In algebraic geometry, the module of Kähler differentials of a commutative ring RR corresponds under the Serre–Swan theorem to the cotangent bundle of the Zariski spectrum? of RR.

In contrast, the module of Kähler differentials of the commutative real algebra of smooth functions on a smooth manifold MM receives a canonical map from the module of smooth sections of the cotangent bundle of MM that is quite far from being an isomorphism.

An example illustrating this point is M=RM=\mathbf{R}, since in the module of (traditionally defined) Kähler differentials of C (M)C^\infty(M) we have d(exp(x))exp(x)dxd(exp(x))\ne exp(x) dx, where exp:RR\exp\colon\mathbf{R}\to\mathbf{R} is the exponential function and x=id Rx=id_{\mathbf{R}}. That is to say, the traditional algebraic notion of a Kähler differential is unable to deduce that exp=exp\exp'=\exp using the Leibniz rule.

However, this is not a defect in the conceptual idea itself, but merely a failure to use the correct formalism. The appropriate notion of a ring in the context of differential geometry is not merely a commutative real algebra, but a more refined structure, namely, a C^∞-ring.

This notion comes with its own variant of commutative algebra. Some of the resulting concepts turn out to be exactly the same as in the traditional case. For example, ideals of C^∞-rings and modules over C^∞-rings happen to coincide with ideals and modules in the traditional sense. Others, like derivations, must be defined carefully, and definitions that used to be equivalent in the traditional algebraic context need not remain so in the context of C^∞-rings.

Observe that a map of sets d:AMd\colon A\to M (where MM is an AA-module) is a derivation if and only if for any real polynomial f(x 1,,x n)f(x_1,\ldots,x_n) the chain rule holds:

d(f(a 1,,a n))= ifx i(x 1,,x n)dx i.d(f(a_1,\ldots,a_n))=\sum_i {\partial f\over\partial x_i}(x_1,\ldots,x_n) dx_i.

Indeed, taking f(x 1,x 2)=x 1+x 2f(x_1,x_2)=x_1+x_2 and f(x 1,x 2)=x 1x 2f(x_1,x_2)=x_1 x_2 recovers the additivity and Leibniz property of derivations, respectively.

Observe also that ff is an element of the free commutative real algebra on nn elements, i.e., R[x 1,,x n]\mathbf{R}[x_1,\ldots,x_n].

If we now substitute C^∞-rings for commutative real algebras, we arrive at the correct notion of a derivation for C^∞-rings:

Definition

A C^∞-derivation of a C^∞-ring AA is a map of sets AMA\to M (where MM is a module over AA) such that the following chain rule holds for every smooth function fC (R n)f\in\mathrm{C}^\infty(\mathbf{R}^n):

d(f(a 1,,a n))= ifx i(x 1,,x n)dx i,d(f(a_1,\ldots,a_n))=\sum_i {\partial f\over\partial x_i}(x_1,\ldots,x_n) dx_i,

where both sides use the structure of a C^∞-ring to evaluate a smooth real function on a collection of elements in AA.

The module of Kähler C^∞-differentials can now be defined in the same manner as ordinary Kähler differentials, using C^∞-derivations instead of ordinary derivations.

Theorem

(Dubuc, Kock, 1984.) The module of Kähler C^∞-differentials of the C^∞-ring of smooth functions on a smooth manifold MM is canonically isomorphic to the module of sections of the cotangent bundle of MM.

References

Created on September 16, 2024 at 16:05:34. See the history of this page for a list of all contributions to it.