1 January 2003
Date: Wed, 1 Jan 2003 14:42:03 +0100 (CET) From: Eugen Leitl <eugen@leitl.org> To: <cypherpunks@lne.com> Subject: Re: biological systems and cryptography On Wed, 1 Jan 2003 you wrote: > What's the latest news on Adelman's cryptological > soup? Once his DNA crypto was touted as a > substantial breakthrough for crypto, though since > overshadowed by quantum crypto smoke-blowing. DNA computes very slowly; it's bound by viscous drag and brownian noise to sample nucleotide pair matching. Dry NEMS operates roughly in 100 GHz regime, tops (complex devices would typically run at 10-100 MHz). Electronical components already operate in multiple THz range, I presume the ceiling for suitable molecular scale components suitably cooled and/or running in ballistic or even superconducting regime, using mostly reversible logic (the ratio of ones to zeroes of adjacent bits never changes much during each step) lies somewhat higher, though it is difficult to predict how high. So they are faster than current computers, but the real power comes because you count your individual computer components in moles. That's the big jump, as seen from our current capabilities. Once you're there you can only scale up by making more moles of computronium (a molecular crystal with units being individual computers). You can make lots of moles from free floating junk in space by automatic autoamplifying fabbing, but clearly other people would want to use that resource for themselves, at least on the long run. But a few cubic miles looks rather doable. Given a circumsolar cloud of hardware a few lightminutes across (you need about the mass of Mercury to completely intercept the entire solar output in a relatively low, uncomfortably hot orbit) you can do a lot of brute forcing, but it's still finite. The interesting part is when you can make your molecular stuff act as qubits at high rates of entanglement. QM is much overhyped, so it's dubious one can make handheld devices equivalent to above circumsolar machine. I expect first hybrid 2d molecular memories in about a decade, 3d integrated stuff will take another decade, or so. That's all without invoking machine-phase autoassembly, just synthetic chemistry/biology.