The reason the probability that the kth card will end up in slot n is 1/n is because the nth iteration completely determines what card ends up in slot n! (<--- that's an exclamation point, not a factorial :-).
Think about it. On the last iteration of the loop, you have some random permutation... and the kth card is sitting in some slot. The probability it moves into slot n is just the probability that you pick that kth card at random. Assuming you pick cards with equally likely probability, that probability is 1/n.
Hope this helps.
You might be thinking I made a faulty assumption. Namely, you might be wondering... what if the kth card can end up in different slots with different probabilities? What if the "random shuffling" isn't really random? This is why only the last iteration matters:
Let pi denote the probability that the kth card is in slot i on the n-1 iteration (ie - it is in slot i right before the end).
Then the probability that card k ends up in slot n (on the nth iteration) is:
(1/n)p1 + (1/n)p2 + ... + (1/n)pn
But notice we can factor the (1/n), so we have:
(1/n)(p1 + p2 + ... + pn)
And because these are probabilities, it should be obvious that the sum of the pi's (i = 1 to n) must equal 1. So we are left with just (1/n).
That is just being a bit more formal to show that the randomness of the state of affairs before the nth iteration really does not matter.