Let A, B, and C be spheres that are tangent pairwise and whose points of tangency are distinct. Let {D1, D2, ..., Dn} be a set of spheres each of which is tangent to spheres A, B, and C. For i = 1 to n, Di is externally tangent to Di+1 (where Dn+1 = D1).
What is the value of n?
Here are my thoughts on this problem. I'm not going to prove anything rigorously, though. I'm assuming the relative sizes of A, B and C are arbitrary, and that everything lives in Euclidean 3-space.
I posit that for any three mutually tangent spheres, you can find two spheres tangent to all three that are themselves externally tangent. Thus I'm willing to assume n is at least 2. I'm not going to prove that, though. Can anyone come up with a proof/counterexample?
For the maximum value of n, I'll start with the case where all spheres are solid, and therefore externally tangent. Suppose A, B, and C are the same size. To be tangent to all three, the centers of the D's must be colinear, so there cannot be more than 2 that are pairwise-tangent.
Now suppose A and B are the same size, and C is smaller. In this case, it is possible for the D's to 'wrap all the way around' C to form a mutually tangent ring. Now, If we consider the limiting case here (picture two planets and a golf ball), we approach two parallel planes with a sphere between. in this case, we can find 6 D spheres, the same size as C, that form a ring around C. Of course, this is a limiting case, so it isn't strictly allowed, and i don't know if it's really possible to find a 6-D configuration in any real case, but i posit that for A and B bigger than C, N is somewhere between 2 and 6 inclusive.
Now, what about the case where A is big, and B and C are small? If B and C are the same size, then the D's can form a loop in the tangent plane between B and C. I can't say for sure without actually crunching the numbers, but I'm pretty sure i could come up with an arrangement of this type that supports 5 D's (one small D directly between A, B, and C, two slightly larger on either side, and two bigger ones that meet 'behind' B and C). more than 5, though, doesn't seem possible (sound like a challenge? by all means, prove me wrong!).
Finally, lets relax the external tangency assumption a bit and assume that A is hollow, and B and C are each half the diameter of A, and fit snugly inside. In this arrangement, you can fit six D's inside A, each of which has diameter 1/3 that of A, and they form a closed ring.
Therefore, I posit that n is at least 2 and at most 6, depending on the specifics of A, B, and C.
BTW: in the case of a hollow A, if we increase the size of B relative to C, the limiting case is again parallel planes with a sphere in between, which also yields n = 6. Is this true for all cases in between? In other words, If B and C are externally tangent and each internally tangent to A, is n always 6?
hand waving
