nLab smooth differential forms form the free C^∞-DGA on smooth functions

Background

See the article Kähler C^∞-differentials of smooth functions are differential 1-forms for the necessary background for this article, including the notions of C^∞-ring, C^∞-derivation, and Kähler C^∞-differential.

Idea

In algebraic geometry, (algebraic) differential forms on the Zariski spectrum? of a commutative ring $R$ (or a commutative $k$ -algebra $R$ ) can be defined as the free commutative differential graded algebra on $R$ .

This definition does not quite work for smooth manifolds: as already explained in the article Kähler C^∞-differentials of smooth functions are differential 1-forms, the notion of a Kähler differential must be refined in order to extract smooth differential 1-forms from the C^∞-ring of smooth functions on a smooth manifold $M$ .

Thus, in order to get the algebra of smooth differential forms, the notion of a commutative differential graded algebra must likewise be adjusted.

Definition

A commutative differential graded C^∞-ring is a real commutative differential graded algebra $A$ whose degree 0 component $A_0$ is equipped with a structure of a C^∞-ring in such a way that the degree 0 differential $A_0\to A_1$ is a C^∞-derivation.

With this definition, we can recover smooth differential forms in a manner similar to algebraic geometry, deducing the following consequence of the Dubuc–Kock theorem for Kähler C^∞-differentials.

Theorem

The free commutative differential graded C^∞-ring on the C^∞-ring of smooth functions on a smooth manifold $M$ is canonically isomorphic to the differential graded algebra of smooth differential forms on $M$ .

Application: the Poincaré lemma

The Poincaré lemma becomes a trivial consequence of the above theorem.

Proposition

For every $n\ge0$ , the canonical map

\mathbf{R}[0]\to \Omega(\mathbf{R}^n)

is a quasi-isomorphism of differential graded algebras.

Proof

(Copied from the MathOverflow answer.) The de Rham complex of a finite-dimensional smooth manifold $M$ is the free C^∞-dg-ring on the C^∞-ring $C^\infty(M)$ . If $M$ is the underlying smooth manifold of a finite-dimensional real vector space $V$ , then $C^\infty(M)$ is the free C^∞-ring on the vector space $V^*$ (the real dual of $V$ ). Thus, the de Rham complex of a finite-dimensional real vector space $V$ is the free C^∞-dg-ring on the vector space $V^*$ . This free C^∞-dg-ring is the free C^∞-dg-ring on the free cochain complex on the vector space $V^*$ . The latter cochain complex is simply $V^*\to V^*$ with the identity differential. It is cochain homotopy equivalent to the zero cochain complex, and the free functor from cochain complexes to C^∞-dg-rings preserves cochain homotopy equivalences. Thus, the de Rham complex of the smooth manifold $V$ is cochain homotopy equivalent to the free C^∞-dg-ring on the zero cochain complex, i.e., $\mathbf{R}$ in degree 0.

References

E. J. Dubuc, A. Kock, On 1-form classifiers, Communications in Algebra 12:12 (1984), 1471–1531. doi.

Created on September 16, 2024 at 16:24:58. See the history of this page for a list of all contributions to it.