The new clock is based on an energy transition in a single trapped mercury ion (a mercury atom that is missing one electron). Building a clock based on such a high-frequency transition was previously impractical because it requires both "capturing" the ion and holding it very still to get accurate readings, and having a mechanism that can "count" the ticks accurately at such a high frequency.

Precise time-keeping underlies much of the structure of modern civilization, including navigation, electric power management, and communications. It also has made possible significant advances in astronomy and physics. Today the best clocks are based on a natural atomic resonance of the cesium atom -- the atomic equivalent of a pendulum. For example, NIST-F1, one of the world's most accurate time standards, neither gains nor loses a second in 20 million years.

How good a clock is depends on stability and accuracy -- whether the clock provides a constant, unchanging output frequency, and how close the measured frequency is to the fundamental atomic resonance that provides the clock's "tick." One advantage of the new clock is that it ticks much faster.

Today's international time and frequency standards, such as NIST-F1, measure an atomic resonance of about 9 billion cycles per second. By contrast, the new NIST device monitors an optical frequency more than 100,000 times higher or about 1 quadrillion cycles per second.

In principal, a frequency standard or clock based on the new mechanism could be proportionately more accurate and stable than the current standard. Indeed, the new device already has demonstrated a short-term stability significantly better than any existing atomic clock. Researchers will continue work to determine its accuracy.

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