H-object

In mathematics, specifically homotopical algebra, an H-object^[1] is a categorical generalization of an H-space, which can be defined in any category ${\displaystyle {𝒞}}$ with a product ${\displaystyle \times }$ and an initial object ${\displaystyle *}$. These are useful constructions because they help export some of the ideas from algebraic topology and homotopy theory into other domains, such as in commutative algebra and algebraic geometry.

Definition

In a category

with a product

and initial object

, an H-object is an object

together with an operation called multiplication together with a two sided identity. If we denote

, the structure of an H-object implies there are maps

${\displaystyle \begin{array}{rl}\epsilon & :*\to X\\ \mu & :X\times X\to X\end{array}}$

which have the commutation relations

${\displaystyle \mu (\epsilon \circ u_X,i{d}_X)=\mu (i{d}_X,\epsilon \circ u_X)=i{d}_X}$

Examples

Magmas

All magmas with units are H-objects in the category ${\displaystyle \text{<mrow data-mjx-texclass="ORD">Set</mrow>}}$.

H-spaces

Another example of H-objects are H-spaces in the homotopy category of topological spaces ${\displaystyle \text{Ho}(\text{<mrow data-mjx-texclass="ORD">Top</mrow>})}$.

H-objects in homotopical algebra

In homotopical algebra, one class of H-objects considered were by Quillen^[1] while constructing André–Quillen cohomology for commutative rings. For this section, let all algebras be commutative, associative, and unital. If we let

be a commutative ring, and let

be the undercategory of such algebras over

(meaning

-algebras), and set

be the associatived overcategory of objects in

, then an H-object in this category

is an algebra of the form

where

is a

-module. These algebras have the addition and multiplication operations

${\displaystyle \begin{array}{rl}(b\oplus m)+(b^{\prime }\oplus m^{\prime })& =(b+b^{\prime })\oplus (m+m^{\prime })\\ (b\oplus m)\cdot (b^{\prime }\oplus m^{\prime })& =(b{b}^{\prime })\oplus (b{m}^{\prime }+b^{\prime }m)\end{array}}$

Note that the multiplication map given above gives the H-object structure

. Notice that in addition we have the other two structure maps given by

${\displaystyle \begin{array}{rl}{u}_{B\oplus M}(b\oplus m)& =b\\ \epsilon (b)& =b\oplus 0\end{array}}$

giving the full H-object structure. Interestingly, these objects have the following property:

${\displaystyle {\text{Hom}}_{(A\mathrm{\setminus }R)/B}(Y,B\oplus M)\cong {\text{Der}}_A(Y,M)}$

giving an isomorphism between the

-derivations of

to

and morphisms from

to the H-object

. In fact, this implies

is an abelian group object in the category

since it gives a contravariant functor with values in Abelian groups.

See also

• André–Quillen cohomology
• Cotangent complex
• H-space

References