I have no comment on the practicality of this as a storage scheme. As to the mathematical problem of counting the number of distinct arrangements, this is made to order for the Polya Counting Theorem. -- Gene From: Keith F. Lynch <kfl@KeithLynch.net> To: math-fun@mailman.xmission.com Sent: Monday, June 20, 2016 5:44 PM Subject: [math-fun] Data storage in buckminsterfullerene The recent discussion about data storage in diamonds made me wonder about data storage in another stable form of carbon: C60, buckyballs. How many bits can be stored in one buckyball, i.e. fullerene molecule? It's a truncated icosahedron with 32 faces (of which 12 are regular pentagons and 20 are regular hexagons), 90 edges, and 60 vertices. The 60 vertices are carbon atoms. Data can be stored by making some of them C12 and some of them C13. But how much data? The base-2 log of the number of distinct arrangements of C12 and C13 atoms. But how many arrangements are there? If the molecules were not free to rotate, there would be 2^60 arrangements, hence 60 bits. But of course the molecules are free to rotate. The rotation group is order 60. So there are at least 2^60/60 arrangements, hence at least 54 bits. Can anyone think of a practical way to count the arrangements? The obvious way would be to try all 2^60 arrangements and eliminate the ones that are rotations of arrangements that have already been found. But 2^60 is more than 10^18, so that's just barely computationally feasible. Is there a better way? Has someone counted them already? Thanks. This number might seem to be uselessly small, but it isn't, since data could be stored in a large set of buckyballs. Each molecule could contain a 50-bit sequence number and several bits of data, giving several hundred terabytes of total storage. There would be many duplicates to ensure that at least one molecule with each sequence number is found. Several hundred terabytes may not seem like much by today's standards, but it can store the whole of Wikipedia, plus more books than anyone can read in a lifetime, plus more movies than anyone is likely to view in a lifetime. It's a lot larger than the genome of any organism, so it's a lot more practical than living DNA data storage. And 2^50 buckyballs times 600 duplicates of each of them would mass less than one milligram. _______________________________________________ math-fun mailing list math-fun@mailman.xmission.com https://mailman.xmission.com/cgi-bin/mailman/listinfo/math-fun