This approach will work
- Compute the centroid of the longest path in the tree. To do that, use depth-first search to find the vertex x where the max of vertex depths in the tree rooted at x is minimal
- Compute the depth of all vertices in the tree rooted at x using a simple tree traversal
- Group the queries by the index of the connected component into which their query would fall if x was removed
- Iterate over all queries by component. Say your query is (v, d). If depth(v) <= d, then you can just use the d-th ancestor of v as the answer, using a standard approach in O(log n). Otherwise, check if there is a solution vertex w with path(v, w) crossing x and dist(v, w) = d by looking up the depth d - depth(v) in one of the other components (e.g. in O(1) via hashing)
This works because if there is an answer for query (v, d) with depth(v) >= d, then there is a path of length d starting at v that crosses x, due to the property of x.
You can implement steps 1 and 2 using a single depth-first search.
For step 4, you want to keep a hash table that associates depth with vertices in a way that you can remove and add vertices in O(1). Then you can perform it in linear time when working component by component.
The total run time will be O((n + q) * log n).
This can be made online by precomputing the depth data structure from step 4 using persistent binary search trees, again in O(log n) per query.