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First 7-qubit Quantum Computer Developed
AllynKC wrote: "Wired News has this story on the developments in quantum computing. Federal researchers have developed the worlds first 7-qubit quantum computer.
Interesting stuff; but even Wired's toned-down version is, quite honestly, beyond me at some points. Still, the concept of a fully functioning quantum computer intrigues me."
A qubit, as the article says, is a quantum bit. All this means is that there is some quantum system/subsystem where some quality, like spin or energy, can be decomposed into precisely to two states. An ananology would Fourier's theorem: Broadly speaking, it says that you can decompose any "nice" function into an infinite sum of sines and cosines. The quantum world is cool because often, just two basis functions, up and down, are needed to completely (a pun, for you math people) describe a space in which that numerical quality resides.
Such is the case here. The scientists, if I am not mistaken, are manipulating spin. Spin is a fundamental quantity in "classical" quantum mechanics; the spin quality of spin 1/2 particles, like electrons, can be wrestled out of special relativity (first finagled by Dirac); arbitrary spin falls out of special relativity + quantum field theory (if you know group theory, it's pretty simple :-).
Now, I think this experiment uses spin 1/2 particles, i.e. particles whose total "intrinsic angular momentum" is equal to h/(4*pi), where h is Planck's constant. The cool thing about spin 1/2 particles is that their space is completely described by two components, up and down. This is because h/(2*pi) is the smallest angular momentum quantum you can have, so in order for the possible states to be "legal," the differences between any pair of them must be a multiple of h/(2*pi). But since spin 1/2 particles have a total spin of h/(4*pi), the only possible states are -h/(4*pi) and +h/(4*pi).
So what's the deal with NMR? Well, NMR is nothing more than a method for manipulating/measuring spins/magnetic states using electromagnetic radiation. So, if the molecules in question are placed in a magnetic field, then there will be an energy difference between the up, down, and "mixed" states contingent on the alignment of spins w.r.t. to the direction of the magnetic field. This is as if it were possible for a compass to get stuck in the "south" position -- there's some potential energy caught up in there. In the quantum world, one can shoot a photon a system in the "north," or up, state and have it jump to "south," or down, or high-energy state. The simple requirements for the photon: It must have an energy equal to the difference in energy of the two states; and, it must carry the appropriate amount of angular momentum, important for more complex situations. So, these scientists have been able to manipulate bits by shooting radio waves at'em.
So why are 7-qubit systems important? Because, in addition to the "external" or ambient magnetic field, each little particle that has a magnetic moment also generates a magnetic field. Having a "strongly interacting" multi-qubit system gives you a much more reliable bit, because when some flip due to a photon, the stragglers are more likely to flip as well. This will help avoid the dreaded mixed states that can screw with your data in untraceable ways. As noted by Wineland of NIST, this cute strategy has sharply diminishing returns past 15.
The "trans-crotonic" acid is probably just some acid which is transparent to the NMR frequencies they're working at, and is nice all around for refractions, etc.
There is a simple, but informative page at UCSD that has pretty pictures showing what I've been blabbering about ...
I hope I've been helpful w/o being condescending!
*** Proven iconoclast, aspiring epicurean ***