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Optical Atomic Clock Has Most Precise 'Ticks' Ever

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BOULDER, Colo., Dec. 1, 2006 -- Using an ultrastable laser to manipulate strontium atoms trapped in a "lattice" of light, scientists at the National Institute of Standards and Technology (NIST) and the University of Colorado at Boulder have demonstrated the capability to produce the most precise "ticks" ever recorded in an optical atomic clock.

The techniques may be useful in time keeping, precision measurements of high frequencies, and quantum computers using neutral atoms as bits of information, the scientists said.JILAclock.jpg
In JILA's new optical atomic clock, blue laser light is used to cool and trap strontium atoms as the first step before loading them into a "lattice" made of light. The blue light and fluorescing atoms are visible in the magnetic-optical trap, located inside a vacuum chamber. (Photo: Martin Boyd and Tetsuya Ido/JILA)
The JILA strontium lattice design is a leading candidate for next-generation atomic clocks that operate at optical frequencies, which are much higher than the microwaves used in today's standard atomic clocks and divide time into smaller, more precise units. JILA is a cooperative institute of CU-Boulder and NIST and is located on the CU-Boulder campus.

The JILA group, led by Jun Ye of NIST and CU-Boulder, achieved the highest "resonance quality factor" -- indicating strong, stable signals when a very specific frequency of laser light excites the atoms -- ever recorded in coherent spectroscopy, or studies of interactions between matter and light.

"We can define the center, or peak, of this resonance with a precision comparable to measuring the distance from the Earth to the sun with an uncertainty the size of a human hair," said Martin Boyd, a CU-Boulder graduate student and first author of a paper on the work. This enabled observation of very subtle sublevels of the atoms' electronic energy states created by the magnetic "spin" of their nuclei.

The new strontium clock is among the best optical atomic clocks described to date in published literature. It is currently less accurate overall than NIST's mercury-ion charged-atom clock. Although the strontium clock operates at a lower optical frequency, with fewer than half as many ticks per time period, the JILA clock produces much stronger signals, and its "resonant" frequency -- the exact wavelength of laser light that causes the atoms to switch back and forth between energy levels -- was measured with higher resolution than in the mercury clock. The result is a frequency "ruler" with finer hash marks.


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Improved time and frequency standards have many applications. For instance, ultraprecise clocks can be used to improve synchronization in navigation and positioning systems, telecommunications networks, and wireless and deep-space communications. Better frequency standards can be used to improve probes of magnetic and gravitational fields for security and medical applications, and to measure whether "fundamental constants" used in scientific research might be varying over time -- a question that has enormous implications for understanding the origins and ultimate fate of the universe.

One of JILA's major innovations enabling the new level of precision is a customized probe laser that is highly resistant to "noise" caused by vibration and gravity, based on a compact, inexpensive design originally developed by 2005 Nobel laureate Jan Hall, a fellow and senior research associate at JILA. Hall also is affiliated with the CU-Boulder physics department.

The laser can be locked reliably on a single atomic frequency, 430 trillion cycles per second with a "linewidth" or uncertainty of under 2 Hz, 100 times narrower, or more precise, than the Ye group's previously published measurements of the strontium lattice clock.

The lattice consists of a single line of 100 pancake-shaped wells -- created by an intense near-infrared laser beam -- each containing about 100 atoms of the heavy metal strontium. The lattice is loaded by first slowing down the atoms with blue laser light and then using red laser light to further cool the atoms so that they can be captured. Scientists detect the atoms' "ticks" -- 430 trillion per second -- by bathing them in very stable red light at slightly different frequencies until they find the exact frequency that the atoms absorb best.

Optical lattices constrain atom motion and thereby reduce systematic errors that need to be managed in today's standard atomic clocks, such as NIST-F1, that use moving balls of cold atoms.

Lattices containing dozens of atoms also produce stronger signals than clocks relying on a single ion, such as mercury. In addition, the JILA clock ensures signal stability -- a particular challenge with large numbers of atoms -- by using a carefully calibrated lattice design to separate control of internal and external atom motions. Similar work is under way at a number of standards labs across the globe, including the NIST ytterbium atoms work.

The work is described in the Dec. 1 issue of Science. It may enable quantum information to be processed and stored in the nuclear spins of neutral atoms, and enable logic operations to proceed for longer periods of time, the scientists said. The enhanced measurement precision also could make it easier for scientists to use optical lattices to engineer condensed matter systems for massively parallel quantum measurements.

For more information, visit: http://jilawww.colorado.edu

Published: December 2006
Glossary
atomic clock
An atomic clock is a highly precise timekeeping device that uses the vibrations or oscillations of atoms as a reference for measuring time. The most common type of atomic clock uses the vibrations of atoms, typically cesium or rubidium atoms, to define the length of a second. The principle behind atomic clocks is based on the fundamental properties of atoms, which oscillate at extremely stable and predictable frequencies. The primary concept employed in atomic clocks is the phenomenon of...
clock
A signal, generated by an oscillator, that provides the means of synchronization of operations in a data communications network.
lattice
In photonics, a lattice refers to a periodic arrangement of optical elements or structures, often on a microscopic or nanoscopic scale. These optical lattices can be created using various techniques such as lithography, etching, or deposition processes. The arrangement of these elements forms a regular grid-like pattern, analogous to the crystal lattice in solid-state physics. One common application of optical lattices is in photonic crystals, which are engineered materials with periodic...
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
optical
Pertaining to optics and the phenomena of light.
photonics
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
quantum
The term quantum refers to the fundamental unit or discrete amount of a physical quantity involved in interactions at the atomic and subatomic scales. It originates from quantum theory, a branch of physics that emerged in the early 20th century to explain phenomena observed on very small scales, where classical physics fails to provide accurate explanations. In the context of quantum theory, several key concepts are associated with the term quantum: Quantum mechanics: This is the branch of...
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