The following is optimal bound:
If p <= n/log n you can do it in O(n/p) time; otherwise it's O(log n) i.e. when p>n/log n you gain nothing compared to p=n/log n.
Proof - lower bound:
Claim 1: You can never do faster than Ω(n/p), because p processors can give only speedup of p
Claim 2: You can never do faster than Ω(log n), because of CREW model (see unforgiven's paper); if you want to check if a 0-1 array has at least one 1, you need O(log n) time.
Proof - upper bound:
Claim 3: You can find maximum using n/log n processors and in O(log n) time
Proof: It is easy to find maximum using n processors and log n time; but in fact, in this algorithm most processors are dormant most of the time; by suitable dovetailing, (see e.g. Papadimitriou's complexity book) their number can be lowered to n/log n.
Now, given less than n/log n processors you can give work assigned to K processors to 1 processor, this divides processor requirement by K and multiplies required time by K.
Let K=(n/log n)/p; the previous algorithm runs in time O(K log n) = O(n/p), and requires n / (log n * K) = p processors.
Edited: I just realized that when p <= n/log n, dasblinkenlight's algorithm has the same asymptotic runtime:
n/p + log p <= n/p + log(n/log n) <= n/p + log n <= n/p + n/p <= 2n/p = O(n/p)
so you can use that algorithm, which has complexity O(n/p) when p <= n/log n and O(log n) otherwise.