Physicists Show ion Pairs Perform Enhanced 'Spooky Action' -

Physicists Show ion Pairs Perform Enhanced 'Spooky Action'

Adding to strong recent demonstrations that particles of light perform what Einstein called "spooky action at a distance," in which two separated objects can have a connection that exceeds everyday experience, physicists at the National Institute of Standards and Technology (NIST) have confirmed that particles of matter can act really spooky too.
The NIST team entangled a pair of beryllium ions (charged atoms) in a trap, thus linking their properties, and then separated the pair and performed one of a set of possible manipulations on each ion's properties before measuring them. Across thousands of runs, the pair's measurement outcomes in certain cases matched, or in other cases differed, more often than everyday experience would predict. These strong correlations are hallmarks of  entanglement.
What's more, statistical calculations found the ion pairs displayed a rare high level of spookiness."We are confident that the ions are 67 percent spooky," said Ting Rei Tan, lead author of a new Physical Review Letters paper about the experiments.The experiments were "chained" Bell tests, meaning that they were constructed from a series of possible sets of manipulations on two ions. Unlike earlier experiments, these were enhanced Bell tests in which the number of possible manipulations for each ion was chosen randomly from sets of at least two and as many as 15 choices.This method produces stronger statistical results than conventional Bell tests. That's because as the number of options grows for manipulating each ion, the chance automatically decreases that the ions are behaving by classical, or non-quantum, rules. According to classical rules, all objects must have definite "local" properties and can only influence each other at the speed of light or slower. Bell tests have been long used to show that through quantum physics, objects can break one or both of these rules, demonstrating .Conventional Bell tests produce data that are a mixture of local and spooky action. Perfect chained Bell tests can, in theory, prove there is zero chance of local influence. The NIST results got down to a 33 percent chance of local influence—lower than conventional Bell tests can achieve, although not the lowest ever reported for a chained , Tan said.However, the NIST experiment broke new ground by closing two of three "loopholes" that could undermine the results, the only chained Bell test to do this using three or more options for manipulating material particles. The results are good enough to infer the high quality of the entangled states using minimal assumptions about the experiment—a rare achievement, Tan said.Last year, a different group of NIST researchers and collaborators closed all three loopholes in conventional Bell tests with particles of light. The new ion experiments confirm again that spooky action is real."Actually, I believed in quantum mechanics before this experiment," Tan said with a chuckle. "Our motivation was we were trying to use this experiment to showcase how good our trapped ion quantum computing technology is, and what we can do with it."The researchers used the same ion trap setup as in previous quantum computing experiments. With this apparatus, researchers use electrodes and lasers to perform all the basic steps needed for quantum computing, including preparing and measuring ions' quantum states; transporting ions between multiple trap zones; and creating stable quantum bits (qubits), qubit rotations, and reliable two-qubit logic operations. All these features were needed to conduct the chained Bell tests. Quantum computers are expected to one day solve problems that are currently intractable such as simulating superconductivity (the flow of electricity without resistance) and breaking today's most popular data encryption codes.In NIST's chained Bell tests, the number of settings (options for different manipulations before measurement) ranged from two to 15. The manipulations acted on the ions' internal energy states called "spin up" or "spin down." The researchers used lasers to rotate the spins of the ions by specific angles before the final measurements.
The NIST experiments did not close the locality loophole, which is open if it is possible for the choice of settings to be communicated between the ions. To close this loophole, one would need to separate the ions by such a large distance that communication between them would be impossible, even at light speed. In the NIST experiment, the ions had to be positioned close together (at most, 340 micrometers apart) to be entangled and subsequently measured, Tan explained.

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