valjok said:
Why not? Countable is something that has one-to-one correspondence with naturals and I can definitely count them.
Start counting the natural numbers and let me know when you're done :D.
I cannot understand counting (enumerating, getting next index of) uncountable.
Thanks.
Do you see how the following picture:
http://en.wikipedia.org/wiki/File:Omega_squared.png
shows a well-ordering of \omega_0 copies of \omega_0? A well order like this is said to have type \omega_0\cdot\omega_0 or simply, \omega_0^2. Now this is still countable, since one can find a bijection between the "matchsticks" in this picture and the natural numbers (just as one can find a bijection between \mathbb{N}\times\mathbb{N} and \mathbb{N}). However the order type here is not \omega_0, because you can see it has an initial part that's ordered like \omega_0, but then it goes on.
So \omega^2 is a countable ordinal, but it has larger order type than \omega. Technically, we could write:
\omega < \omega^2;\ \ |\omega| = |\omega^2| = |\mathbb{N}|
Does this make sense to you so far?
Now, can you imagine the collection of all countable ordinals?
ω, ω + 1, ω + 2, …, ω·2, ω·2 + 1, …, ω2, …, ω3, …, ω
ω, …, ω
ωω, …, ε
0, ….
Can you see that this collection will be (a) uncountable (by virtue of containing all the countable ordinals), and (b) well-ordered (since you can see it's a listing of increasing ordinals)? And for any element \alpha in this set (e.g. ω
ω+5), you can find its successor \alpha+1 (e.g. ω
ω+6) which is a countable well-ordering that looks like \alpha, and then has one more element tacked on at the end?
