I think that you're confusing two pieces of terminology. There are "buckets" in the hash table sense, which are some internal implementation detail used to distribute elements evenly so that lookups tend not to scan over too many useless elements. There are also "buckets" in the spatial sense, which are partitions of space into regions so that elements belong to exactly one bucket. Typically, you will have control over the spatial bucketing system yourself (you get to pick where everything is split), but a hash table will not let you control the buckets very precisely. You may get to pick an initial size, but if the hash table thinks it's a good idea to increase that size in order to improve performance, it almost certainly will do so. If it didn't, lookup times would be substantially worse.
If you want to split space up into a grid and then distribute points into that grid, the best way to do this would be to create a 2D array (either with raw arrays or using some grid linearization) of
std::unordered_maps, each of which just holds points in one particular region of space. That way, if you want to look up an element, you go to the map holding points just for that bucket, then ask the map to look up the value, at which point it consults its own internal bucketing system to find the point that you want. This means that if you want to split up the points so that you can do interesting queries on the regions of space, the points are stored in buckets specifically dedicated to those regions, but within those buckets they're stored in a hash table to make looking up those points take less time.
Alternatively, you might want to consider using a spatial data structure like a quadtree or kd-tree, which store the elements efficiently and let you query every point in a spatial bucket efficiently.
Hope this helps!