So let's suppose that we build the tree this way: given n nodes, take f(n) nodes and set them aside. Then build a tree by building a perfect binary tree where the root has a left subtree that's a perfect binary tree of n - f(n) - 1 nodes and a right subtree that's a chain of length f(n). We'll pick f(n) later.
So what's the average depth in the tree? Since we just want an asymptotic bound, let's pick n such that n - f(n) - 1 is one less than a perfect power of two, say, 2^k - 1. In that case, the sum of the heights in this part of the tree is 1*2 + 2*3 + 4*4 + 8*5 + ... + 2^(k-1) * k, which is (IIRC) about k 2^k, which is just about (n - f(n)) log (n - f(n)) by our choice of k. In the other part of the tree, the total depth is about f(n)^2. This means that the average path length is about ((n - f(n))log (n - f(n)) + f(n)^2) / n. Also, the height of the tree is f(n). So we want to maximize f(n) while keeping the average depth O(log n).
To do this, we need to find f(n) such that
- n - f(n) = Θ(n), or the log term in the numerator disappears and the height isn't logarithmic,
- f(n)^2 / n = O(log n), or the second term in the numerator gets too big.
If you pick f(n) = Θ(sqrt(n log n)), I think that 1 and 2 are satisfied maximally. So I'd wager (though I could be totally wrong about this) that this is as good as you can get. You get a tree of height Θ(sqrt(n log n)) that has average depth Θ(Log n).
Hope this helps! If my math is way off, please let me know. It's late now and I haven't done my usual double-checking. :-)