This is a rough sketch:
Create a segment tree from the data. At each node, besides the usual data like left and right indices, you also store the numbers found in the sub-tree rooted at that node, stored in sorted order. You can achieve this when you construct the segment tree in bottom-up order. In the node just above the leaf, you store the two leaf values in sorted order. In an intermediate node, you keep the numbers in the left child, and right child, which you can merge together using standard merging. There are O(n) nodes in the tree, and keeping this data should take overall O(nlog(n)).
Once you have this tree, for every query, walk down the path till you reach the appropriate node(s) in the given range ([s, e]). As the tutorial shows, one or more different nodes would combine to form the given range. As the tree depth is O(log(n)), that is the time per query to reach these nodes. Each query should be O(log(n)). For all the nodes which lie completely inside the range, find the closest number using binary search in the sorted array stored in those nodes. Again, O(log(n)). Find the closest among all these, and that is the answer. Thus, you can answer each query in O(log(n)) time.
The tutorial I link to contains other data structures, such as sparse table, which are easier to implement, and should give O(sqrt(n)) per query. But I haven't thought much about this.