nLab universal differential envelope

Motivation

$k$-linear derivations of a (not necessarily commutative) associative unital $k$-algebra $A$ with values in $A$-bimodules are often considered: these are $k$-linear maps $d: A\to M$ satisfying the Leibniz identity: $d(a b)=d(a) b+ a d(b)$. One would like to construct a universal construction of that kind.

Definitions

The triple $(A,M,d)$ is then called a differential calculus over $A$, provided $M$ is in the $k$-linear span of all expressions of the form $a d(b_1) d(b_2)\cdots d(b_n)$ where $a,b_1,\ldots,b_n\in A$. Morphisms of differential calculi over $A$ are straightforward to define. A universal object in that category is the universal differential calculus and $\Omega A = M$ in that case is called the universal differential envelope of $A$. It is constructed as the quotient of the tensor algebra $T A$ modulo the ideal generated by the (“augmentation”) kernel $I\subset A\otimes A$ of the multiplication map $A\otimes A\to A$; then $d a = 1\otimes a - a\otimes 1$.

The bimodule $\Omega A$ is in fact a $k$-algebra, generated by degree-$1$ elements (in $A$); differential $d:A\to \Omega A$ can be naturally extended along the inclusion $A\hookrightarrow \Omega A$ to a differential $d:\Omega A\to \Omega A$ satisfying the Leibniz rule, by setting $d 1 = 0$, $d (w y) = d(w) y + (-1)^p w d(y)$, where $w,y$ are forms and $w\in\Omega^p A$ is homogeneous.

References

• A. Connes, Noncommutative Geometry
• R. Coquereaux and D. Kastler, Remarks on the differential envelopes of associative algebras
• F. Bonechi, R. Giachetti, R. Maciocco, E. Sorace, M.Tarlini, Cohomological Properties of Differential Calculi on Hopf Algebras
• H. C. Baehr, A. Dimakis, F. Müller-Hoissen, Differential Calculi on Commutative Algebras
• Folkert Müller-Hoissen?, Introduction to Noncommutative Geometry of Commutative Algebras and Applications in Physics

Discussion

Eric: I have some notes on my personal web, but they need work before transferring them here.