I'm trying to understand what `Monoid`

is from a category theory perspective, but I'm a bit confused with the notation used to describe it. Here is Wikipedia:

In category theory, a monoid (or monoid object) (M, μ, η) in a monoidal category (C, ⊗, I) is an object M together with two morphisms

μ: M ⊗ M → M called multiplication,

η: I → M called unit

My confusion is about the morphism notation. Why is the binary operation `⊗`

a part of the morphism notation? My understanding of a morphism is that it's a kind of function that can map from one type to another (domain to codomain), like `M → M`

. Why is the operation `⊗`

a part of the domain in the definition? The second confusion is about `I`

. Why is `I`

a domain? There is no `I`

object in a `Monoid`

at all. It's just a neutral element of the object `M`

.

I understand that `Monoid`

is a category with one object, an identity morphism, and a binary operation defined on this object, but the notation makes me think that I don't understand something.

Is `M ⊗ M`

somehow related to the cartesian product, so that the domain of the morphism is defined as `M x M`

?

**Edit:** I got a really helpful answer for my question on the Mathematics Stack Exchange.

are-- there's little answer that can be given to "why is the definition that way" other than "because we observe there are a bunch of things we want to talk about uniformly that are that way". So I can't really imagine answering that question sensibly. But I could imagine plausibly answering "How does this definition correspond with the various parts of the set theory definition?". – Daniel Wagner May 18 at 15:58`I -> M`

looks very strange for me. Like it's morphism from object`I`

(which is not object) to`M`

. Or`M ⊗ M`

is kind of domain. But I would really appreciated for any answer. – Bogdan Vakulenko May 18 at 16:25monoidal categoryis something else: they can have much more interesting collections of objects in which (X) and I induce monoid-like structure (the way (,) on Haskell types is associative and absorbs () up to isomorphism). – pigworker May 18 at 16:33monoidalcategory" are essential, and it's where these operators you are asking about come from. You seem to be ignoring them. – luqui May 18 at 17:56