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Physical Measurement Laboratory / Time and Frequency Division

Time Realization and Distribution

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NIST-F1 Cesium Fountain Atomic Clock

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NIST F1
Credit: Copyright Geoffrey Wheeler

The Primary Time and Frequency Standard for the United States

NIST-F1, the nation's primary time and frequency standard, is a
cesium fountain atomic clock developed at the NIST laboratories in
Boulder, Colorado. NIST-F1 contributes to the international group of
atomic clocks that define Coordinated Universal Time (UTC), the
official world time. Because NIST-F1 is among the most accurate
clocks in the world, it makes UTC more accurate than ever before.

The uncertainty of NIST-F1 is continually improving. In 2000 the
uncertainty was about 1 x 10^-15, but as of January 2013, the
uncertainty has been reduced to about 3 x 10^-16, which means it
would neither gain nor lose a second in more than 100 million years!
The graph below shows how NIST-F1 compares to previous atomic clocks
built by NIST. It is now approximately ten times more accurate than
NIST-7, a cesium beam atomic clock that served as the United State's
primary time and frequency standard from 1993-1999.

Technical Description

NIST-F1 is referred to as a fountain clock because it uses a
fountain-like movement of atoms to measure frequency and time
interval. First, a gas of cesium atoms is introduced into the clock's
vacuum chamber. Six infrared laser beams then are directed at right
angles to each other at the center of the chamber. The lasers gently
push the cesium atoms together into a ball. In the process of
creating this ball, the lasers slow down the movement of the atoms
and cool them to temperatures near absolute zero.

Uncertainty of NIST Time and Frequency Standards

Two vertical lasers are used to gently toss the ball upward (the
"fountain" action), and then all of the lasers are turned off. This
little push is just enough to loft the ball about a meter high
through a microwave-filled cavity. Under the influence of gravity,
the ball then falls back down through the microwave cavity.

The round trip up and down through the microwave cavity lasts for
about 1 second. During the trip, the atomic states of the atoms might
or might not be altered as they interact with the microwave signal.
When their trip is finished, another laser is pointed at the atoms.
Those atoms whose atomic state were altered by the microwave signal
emit light (a state known as fluorescence). The photons, or the tiny
packets of light that they emit, are measured by a detector.

Cesium Fountain Oscillator

This process is repeated many times while the microwave signal in the
cavity is tuned to different frequencies. Eventually, a microwave
frequency is found that alters the states of most of the cesium atoms
and maximizes their fluorescence. This frequency is the natural
resonance frequency of the cesium atom (9,192,631,770 Hz), or the
frequency used to define the second.

The combination of laser cooling and the fountain design allows
NIST-F1 to observe cesium atoms for longer periods, and thus achieve
its unprecedented accuracy. Traditional cesium clocks measure
room-temperature atoms moving at several hundred meters per second.
Since the atoms are moving so fast, the observation time is limited
to a few milliseconds. NIST-F1 uses a different approach. Laser
cooling drops the temperature of the atoms to a few millionths of a
degree above absolute zero, and reduces their thermal velocity to a
few centimeters per second. The laser cooled atoms are launched
vertically and pass twice through a microwave cavity, once on the way
up and once on the way down. The result is an observation time of
about one second, which is limited only by the force of gravity
pulling the atoms to the ground.

As you might guess, the longer observation times make it easier to
tune the microwave frequency. The improved tuning of the microwave
frequency leads to a better realization and control of the resonance
frequency of cesium. And of course, the improved frequency control
leads to what is one of the world's most accurate clocks.

Video Demonstration of How a Cesium Fountain Works
Video Demonstration of How a Cesium Fountain Works
Time and frequency

Contacts

  * Vladislav Gerginov
    vladislav.gerginov@nist.gov
    (303) 497-7366

Created August 26, 2009, Updated October 9, 2020
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