This might be a crude suggestion, and I'm sure it can be improved, but here's a thought:
First, store your positions in such a way that you can access them in constant time given a specific object. For instance, if you want to access them directly through your entities, you can store the position structs in a list/vector and give each entity a pointer/reference to its position.
Second, store an entity pointer/reference or GUID in the same struct as the entity position, so you can identify an entity based on a position object. (There is probably a better way I'm not thinking of right now though.)
Third, utilize some of the principles of sweep and prune/sort and sweep (common in 3D games): Keep two sorted position lists/vectors, one sorted in the x direction and the other sorted in the y direction. One can hold the actual position objects, and the other can hold pointers/references. These lists can take advantage of temporal coherence, so the cost of keeping them sorted shouldn't be too high, unless there's a lot of fast and chaotic movement.
An advantage of this setup is that it's really easy to figure out where every object is relative to each other. Want to know how many objects are within 10 squares of Billy the Elf in either direction? Check Billy's position and iterate forward/backward through both lists until you reach an entity more than 10 squares away in each direction.
If you're interested in the concept, look up sort and sweep (also known as sweep and prune). You'd only be using the first half of the algorithm, but it's used for broad-phase collision detection in practically every major 3D physics engine, so you know that it has to be fast in general. ;) There's a lot of information floating around about it, so you'll probably find much more sophisticated implementation ideas floating around too. (For instance, I don't like the indirection involved in storing a sorted list of pointers/references to position structs; working with the actual structs is more cache-efficient, but then you need to update the position in two places if you want to exploit temporal coherency with persistent arrays. Someone else may have thought of a more clever design that's escaping me right now.)
EDIT: I'd comment on Erik H's idea, but my rep isn't high enough. I just wanted to say that his idea sounds very well suited to your game, especially if you will have a lot of entities tightly packed on the same tile or in a small neighborhood. If I were you, I'd probably try it before the sweep and prune idea. However, it should be accompanied with a well-planned memory management strategy: If you have a dictionary of tile locations that naively map to vectors of entities, you're going to have a lot of memory being allocated and freed when entities move from one tile to another. Instead, you'll want to implement his idea as something more like a dictionary/linked list combo:
The dictionary keys would be tile positions, and the dictionary would return a single pointer to a linked list node. This node would be part of a linked list of all entities on the same tile. Whenever an entity moves from one tile to another, it will be removed from its current linked list and added to the new one. If an entity moves to an empty tile, it will be in a linked list all on its own, and it should be added to the dictionary. When the last entity moves from a tile, the entry for that tile should be removed from the dictionary. This will allow you to move around entities without continual dynamic allocation/deallocation, since you're just updating pointers (and the dictionary will probably be pretty memory efficient).
Note that you don't have to store full-blown entities in the linked lists, either; you can easily create your linked list out of lightweight objects (containing a pointer or GUID to the actual entity).