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Atomic fountain reveals ‘gravitational red shift’

Fountains of caesium atoms in a superposition of quantum states help confirm Einstein's general relativity to astounding accuracy

YOUR watch runs a tiny bit faster at the top of Everest, where Earth鈥檚 gravity is slightly weaker, than it does at sea level. This difference is dubbed the 鈥済ravitational red shift鈥 (GRS) and is one of the trickiest predictions of general relativity to measure because the effect is so small. Now the accuracy of measurement has been improved by a factor of 10,000.

Holger M眉ller at the University of California, Berkeley, decided to reanalyse a decade-old experiment. In the 1990s, a team led by Nobel laureate Steven Chu made an 鈥渁tomic fountain鈥 of caesium atoms, launching them 30 centimetres into the air. A pulse of laser light struck the atoms as they neared their zenith, which kicked them into a two-state quantum superposition. One of the states was given extra momentum, causing it to rise to a slightly higher altitude than the other state before falling.

M眉ller realised the atoms and their very rapid oscillations could be treated as tiny 鈥渃locks鈥 and so could be used to measure GRS. The team compared the difference between the two states and discovered that the state that climbed slightly higher had oscillated ever-so-slightly faster than the lower state. With an accuracy of 7 parts in a billion, this measurement is 10,000 times as accurate as the previous one (Nature, ).

General relativity has been questioned by some theories, 鈥渟o it鈥檚 exciting when people can do such high-precision measurements on relativity鈥, says Jun Ye at the University of Colorado in Boulder.

Topics: Quantum science