I'd like to answer my own question, because since I asked it, I understood the answer and had to explain it to others myself and came up with something that I think is slightly more complete than the above (as it is based on the above, it's reasonable : ]).
Here is the way I'd go about it:
When just defined, the
naturals expression looks like that:
naturals = <0:map (+1) naturals>
<...> indicates a thunk, ie something not yet evaluated.
If at some point we need to know if the first element exists (or if it's the empty list), we have to evaluate the expression. It then becomes:
naturals = <0>:<map (+1) naturals>
When we need to know if the second element exists, we have to evaluate
map (+1) naturals. At least a little bit.
To really get what that means, we need the definition of
map _  = 
map f (x:xs) = f x:map f xs
So here, we evaluate
map (+1) naturals up until we know what its first element is. Here it'll be
<0+1>, and the rest of the naturals expresion will be
<map (+1) (tail naturals)>. Those two results were obtained through direct application of the definition above. It's not actually
tail naturals but the pattern matched value that is the tail, but it's a good enough approximation here.
naturals = <0>:<0+1>:<map (+1) (tail naturals)>
Now let's say we need the third argument, by applying once again the definition of
map, we'll obtain:
naturals = <0>:<0+1>:<0+1+1>:<map (+1) (tail (tail naturals))>
naturals = <0>:<0+1>:<0+1+1>:<0+1+1+1>:<map (+1) (tail (tail (tail naturals)))>
The thing that really helped me is to just write down the definition of
map to understand that there was nothing magical about the way Haskell stops the execution of a function "at some random point". And that lazy evaluation really depends on the function used. If map were coded differently, this definition might not be possible.
I wish someone will find that useful :)