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An atomic fountain is a cloud of atoms that is tossed upwards in the Earth's gravitational field by lasers. If it were visible, it would resemble the water in a fountain. While in free-fall, the atoms are measured to set the frequency of an atomic clock.^[1]

The primary motivation behind the development of the atomic fountain derives from the Ramsey method of measuring the frequency of atomic transitions.^[2] In broad strokes, the Ramsey method involves exposing a cloud of atoms to a brief radiofrequency (rf) electromagnetic field; waiting a time T; briefly exposing the cloud to the rf field again; and then measuring what fraction of the atoms in the cloud have transitioned.^[2] If the frequency of the rf field is identical to the atomic transition frequency, 100% of the atoms will have transitioned; if the frequency of the field differs slightly from the transition frequency, some of the atoms will not have transitioned.^[2] By repeatedly sending clouds of atoms through such an apparatus, the frequency of the field can be adjusted to match the atomic transition frequency.^[3]

The precision of the Ramsey method can be increased by increasing the wait time T of the cloud.^[2] The use of an atomic fountain with a cooled atomic cloud allows for wait times on the order of one second, which is vastly greater than what can be achieved by performing the Ramsey method on a hot atomic beam.^[2] This is one reason why NIST-F1, a caesium fountain clock, can keep time more precisely than NIST-7, a caesium beam clock.^[1]

History

The idea of the atomic fountain was first proposed in the 1950s by Jerrold Zacharias.^[4] Zacharias attempted to implement an atomic fountain using a thermal beam of atoms, under the assumption that the atoms at the low-velocity end of the Maxwell–Boltzmann distribution would be of sufficiently low energy to execute a reasonably sized parabolic trajectory.^[5] However, the attempt was not successful because fast atoms in a thermal beam struck the low-velocity atoms and scattered them.^[5]

References

^ ^a ^b How the NIST-F1 Caesium Fountain Clock Works
^ ^a ^b ^c ^d ^e C. J. Foot (2005). Atomic Physics. p. 212.
^ "NIST Launches a New U.S. Time Standard: NIST-F2 Atomic Clock" on YouTube
^ M. A. Kasevich; et al. (1989). "Atomic fountains and clocks". Optics News. 15 (12): 31–32. doi:10.1364/ON.15.12.000031.
^ ^a ^b S. Chu (1998). "The manipulation of neutral particles" (PDF). Rev. Mod. Phys. 70 (3): 685–706. Bibcode:1998RvMP...70..685C. doi:10.1103/RevModPhys.70.685.

[nist-f1-1] How the NIST-F1 Caesium Fountain Clock Works

[foot-2] C. J. Foot (2005). Atomic Physics. p. 212.

[3] "NIST Launches a New U.S. Time Standard: NIST-F2 Atomic Clock" on YouTube

[Kasevich-4] M. A. Kasevich; et al. (1989). "Atomic fountains and clocks". Optics News. 15 (12): 31–32. doi:10.1364/ON.15.12.000031.

[chu-5] S. Chu (1998). "The manipulation of neutral particles" (PDF). Rev. Mod. Phys. 70 (3): 685–706. Bibcode:1998RvMP...70..685C. doi:10.1103/RevModPhys.70.685.

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