I'm trying to get my head around F-algebras, and this article does a pretty good job. I understand the notion of a dual in category theory, but I'm having a hard time understanding how F-coalgebras (the dual of F-algebras) relate to lazy data structures in Haskell.

F-algebras are described with an endofunctor with the function: F a -> a, which makes sense if you think of F a as an expression, and a as the result of evaluating that expression, as the linked article explains it.

Being the dual of F-algebras, the corresponding function for a F-coalgebra would be a -> F a. Wikipedia says that F-coalgebras can be used to create infinite, lazy data structures. How does the a -> F a functon allow one to create infinite, lazy data structures? Also, with that in mind, since Haskell is at it's core lazy, are most data-types in Haskell F-coalgebras instead of F-algebras? Are F-algebras not lazily evaluated?

If data types (or at least the ones that *are* capable of infinite data) are based on F-coalgebras in Haskell, what is the a -> F a function for lists, for example? What is the terminal F-coalgebra for lists?

Making an infinite list [1,2,3,4...] might look like this in Haskell:

```
list = 1 : map (+ 1) list
```

Does this use F-coalgebras somehow? Do infinite data structures require a notion of lazy evaluation and recursion alongside the use of F-coalgebras? Am I missing something here?