To determine which of the numbers between 1 and n are chosen, you will need to ask at least log_{2} n questions. There is no possible way to do better.

The intuition for this answer is as follows. Suppose that you ask a total of k questions. The maximum number of different possible answers you can receive to those questions, even if they're dependent on one another, is 2^{k}. Since there are n possible numbers that could be picked, you need to choose k such that

2^{k} ≥ n

Which happens precisely when

k ≥ log_{2} n

In other words, you have to ask at least log_{2} n questions to be able to even have enough different possible outcomes to associate each possible number with some possible outcome. Since the number of questions must always be a natural number, the minimum number of questions you can ask must be at least ⌈log_{2} n⌉

This is purely a lower bound on the answer. At this point, we can't rule out the possibility that maybe you need far more questions than this to get the answer. However, the fact that we know about the binary search algorithm means that we know that you never need more than ⌈log_{2} n⌉ questions to get the answer, since this is the number of questions you'd ask if you were doing a binary search. This means that the binary search algorithm has to optimal, since there is no possible way of asking a smaller number of questions.

Hope this helps!