A clock accurate to within a tenth of a second over 14 billion years -- the age of the universe -- is the goal of research being reported this week by scientists from three different institutions. To be published in the journal Physical Review Letters, the research provides the blueprint1 for a nuclear clock that would get its extreme accuracy from the nucleus2 of a single thorium ion. Such a clock could be useful for certain forms of secure communication -- and perhaps of greater interest -- for studying the fundamental theories of physics. A nuclear clock could be as much as one hundred times more accurate than current atomic clocks, which now serve as the basis for the global positioning system (GPS) and a broad range of important measurements.
"If you give people a better clock, they will use it," said Alex Kuzmich, a professor in the School of Physics at the Georgia Institute of Technology and one of the paper's co-authors. "For most applications, the atomic clocks we have are precise enough. But there are other applications where having a better clock would provide a real advantage."
Beyond the Georgia Tech physicists3, scientists in the School of Physics at the University of New South Wales in Australia and at the Department of Physics at the University of Nevada also contributed to the study. The research has been supported by the Office of Naval4 Research, the National Science Foundation and the Gordon Godfrey fellowship.
Early clocks used a swinging pendulum5(钟摆) to provide the oscillations needed to track time. In modern clocks, quartz6 crystals provide high-frequency oscillations that act like a tuning7 fork, replacing the old-fashioned pendulum. Atomic clocks derive8 their accuracy from laser-induced oscillations of electrons in atoms. However, these electrons can be affected9 by magnetic and electrical fields, allowing atomic clocks to drift ever so slightly -- about four seconds in the lifetime of the universe.
Because neutrons11 are much heavier than electrons and densely12 packed in the atomic nucleus, they are less susceptible13 to these perturbations(扰动,不安) than the electrons. A nuclear clock should therefore be less affected by environmental factors than its atomic cousin.
"In our paper, we show that by using lasers to orient the electrons in a very specific way, we can use the neutron10 of an atomic nucleus as the clock pendulum," said Corey Campbell, a research scientist in the Kuzmich laboratory and the paper's first author. "Because the neutron is held so tightly to the nucleus, its oscillation(振动) rate is almost completely unaffected by any external perturbations."
To create the oscillations, the researchers plan to use a laser operating at petahertz frequencies -- 10 (15) oscillations per second -- to boost the nucleus of a thorium 229 ion into a higher energy state. Tuning a laser to create these higher energy states would allow scientists to set its frequency very precisely14, and that frequency would be used to keep time instead of the tick of a clock or the swing of a pendulum.