Contents

Definition

A monad $(T,\mu,i)$, is finitary if the underlying endofunctor $T: C \to C$ preserves filtered colimits.

In other words, a finitary monad is a monoid in the category of finitary endofunctors on some category.

Finitary monads and Lawvere theories

A finitary monad $(T,\mu,i)$ on Set is completely determined by its value on all finite ordinals $n\in\mathbb{N}_0$ considered as standard finite sets. $T(n)$ is then the set of $n$-ary operations. The notion of algebraic monad is hence similar to the notion of a nonsymmetric operad in $\mathrm{Set}$, but it is not equivalent, because of the possibility of duplicating or discarding inputs.

More precisely, each finitary monad $T$ defines a Lawvere theory $Th_T$, namely $Th_T = Free_{fin}^{op}$ where $Free_{fin}$ is the category of free algebras $T(n)$ on finite sets (as a full subcategory of $Alg_T$). In fact, the two notions are equivalent: the assignment

defines an equivalence between the category of finitary monads on $Set$ and the category of Lawvere theories. Moreover, the category of $T$-algebras is equivalent to the category of models of $Th_T$. However, a technical advantage of Lawvere theories is that they can be interpreted in categories other than Set: a model of a Lawvere theory $\mathcal{T}$ in a category with cartesian products $C$ is just a product-preserving functor $\mathcal{T} \to C$.

Properties

• The category of finitary monads on a locally finitely presentable $\mathscr{A}$ category is also locally finitely presentable, and is monadic over $[|\mathscr{A}|, \mathscr{A}]$ (see Lack).

Applications

There is an interesting commutativity condition singling out the subclass of commutative algebraic/finitary monads, cf. commutative algebraic theory; they are useful to establish a theory of generalized commutative schemes.

Related concepts

• classifying topos for the theory of objects

References

For a proof of the equivalence between finitary monads and Lawvere theories, see

• J. Adamek and J. Rosicky, Locally presentable and accessible categories (chapter 3), LMS Lecture Notes 189, Cambridge U. Press, 1994.

For properties of the category of finitary monads, see

• Stephen Lack. On the monadicity of finitary monads. Journal of Pure and Applied Algebra 140.1 (1999): 65-73.

Durov’s application of finitary monads to the “field with one element” may be found in:

• Nikolai Durov, A new approach to Arakelov geometry, arxiv/0704.2030

Discussion

This discussion appeared when the page was at algebraic monad.