A first-of-its-kind measurement has quantified a mysterious quantum
bond shared by several particles rather than just two. The experiment, reported in the Dec. 3 Nature, brings physicists closer to understanding the true scope of this link, known as quantum entanglement.
Entanglement interweaves particles’ fates so that some of each particle’s properties, which are inherently uncertain according to quantum mechanics, are tied to those of its partners. Each particle essentially sacrifices its individuality to become part of an umbrella entangled state. While physicists have developed reliable methods for detecting entanglement between pairs of particles, the measurements get tricky when three or more particles are involved.
A team of quantum
physicists from Harvard University measured a property called
entanglement entropy, which quantifies the apparent randomness that
comes with observing just a portion of an entangled whole. Markus
Greiner and colleagues used lasers to create an optical cage with four
compartments, each of which held a rubidium atom chilled to nearly
absolute zero. The researchers could tweak the laser settings to adjust
the height of the walls between compartments. If the walls were low
enough, atoms could exploit their strange quantum ability to occupy
multiple compartments at once. As the four atoms jumped around, they
interacted and established a state of entanglement.
Greiner’s team created a pair of four-compartment systems and confirmed that they were identical using a technique developed for comparing photons. Then the researchers compared portions of the two cages — say, two of the four compartments where atoms could reside. The partial system of one cage differed from the corresponding partial system of the other cage. A difference between parts when the wholes are indistinguishable “only happens if there is entanglement within each system,” Greiner says.
Entanglement interweaves particles’ fates so that some of each particle’s properties, which are inherently uncertain according to quantum mechanics, are tied to those of its partners. Each particle essentially sacrifices its individuality to become part of an umbrella entangled state. While physicists have developed reliable methods for detecting entanglement between pairs of particles, the measurements get tricky when three or more particles are involved.
A team of quantum
physicists from Harvard University measured a property called
entanglement entropy, which quantifies the apparent randomness that
comes with observing just a portion of an entangled whole. Markus
Greiner and colleagues used lasers to create an optical cage with four
compartments, each of which held a rubidium atom chilled to nearly
absolute zero. The researchers could tweak the laser settings to adjust
the height of the walls between compartments. If the walls were low
enough, atoms could exploit their strange quantum ability to occupy
multiple compartments at once. As the four atoms jumped around, they
interacted and established a state of entanglement.Greiner’s team created a pair of four-compartment systems and confirmed that they were identical using a technique developed for comparing photons. Then the researchers compared portions of the two cages — say, two of the four compartments where atoms could reside. The partial system of one cage differed from the corresponding partial system of the other cage. A difference between parts when the wholes are indistinguishable “only happens if there is entanglement within each system,” Greiner says.
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