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Number 388, September 3, 1998 by Phillip F. Schewe and Ben Stein
QUANTUM ERROR CORRECTION has been experimentally demonstrated for the first time, greatly advancing the promise of carrying out interesting calculations with quantum computers (Updates 310 and 367). Skeptics have maintained that quantum computers would crash before carrying out a useful calculation since the devices rely on fragile, easily corrupted quantum states. Proposed in 1995 and developed unceasingly since then, quantum error correction has been all theory up until now. Aiming radio-frequency pulses at a liquid solution of alanine or trichloroethylene molecules, researchers at Los Alamos and MIT (Raymond Laflamme, 505-665-3394) spread a single bit of quantum information onto three nuclear spins in each molecule. Spreading out the information made it harder to corrupt. The bit of information was a combination or "superposition" of the values 0 and 1, so that it represented a little amount of 0 and a little amount of 1 at the same time. Measuring the spins directly would destroy this superposition and force the bit to become a 0 or a 1. So, the researchers instead "entangled" or interlinked the properties of the three spins. This allowed them to compare the spins to see if any new differences arose between them without learning the bit of information itself. With this technique, they were able to detect and fix errors in a bit's "phase coherence," the phase relationship between the quantum waves corresponding to the 0 and 1 states.(D.G. Cory et al., Physical Review Letters, 7 Sept 1998.)
THE COLLISION BETWEEN BASEBALL AND BAT involves an exchange of energy lasting less than 2 milliseconds. Whether the encounter results in a homerun or not (a subject of great interest this year as two players are swinging for the fences at a record clip) depends on the speed of the pitch, the speed of the bat, and the impact point of the bat. But generally the batter will want to make contact near the "sweet spot," about 17 cm from the end of a typical bat. Hitting the ball there imparts the least amount of vibration (and pain) to the batter's hands. Rod Cross of the University of Sydney (r.cross@physics.usyd.edu.au, 011- 61-2-9351-2545) has made a study of the sweet spot and found several surprises; first, that a baseball bat has two equally important modes of vibration and that consequently the bat possesses three sweet spots closely spaced over a few centimeters. And second, that there is no impact spot on the bat where impulse forces on the hands remain entirely zero. (American Journal of Physics, Sept. 1998; journalists can obtain a copy from AIP. Cross' website---mostly about tennis rackets---will soon display information about baseball bats as well.)
SILICYNE, A NEW FORM OF SILICON, has been discovered by physicists at Lobachevsky State University in Nizhni Novgorod, Russia. "Silicyne" is named in analogy with "carbyne," a linear polymer consisting only of carbon atoms. (Silicon and carbon, both with four valence electrons, are gregarious cousins in the Periodic Table.) The researchers (Alexander Mashin, mashin@phys.unn.runnet.ru) made thin films (70-500 nm) of the new material by heating or implanting ions in samples of conventional amorphous silicon. The silicon chains, which might contain up to 100 atoms, are believed to be weakly linked (through 4-8-atom bridges) with other chains into a random network of filaments. Carbyne applications might include super-strong threadlike carbon; silicyne is too new for talk yet of applications. (Fhokhlov et al., Journal of Experimental and Theoretical Physics (JETP) Letters, 10 May 1998.)
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