Accuracy evaluation of NIST-F1

“…The first realizations were at the Standford University (Stephen Chu' group) and at the Paris Ecole Normale Superieure (C. Salomon group) [7,8]. Technology (NIST, Boulder Colorado), the Physikalisch-Technische Bundesanstalt (PTB, Braunschweig, Germany) and Istituto Nazionale Ricerca Metrologica (INRIM, Turin) [9][10][11]. Today, Cs fountains are also operated at the National Physical Laboratory in UK, and at the NICT and at the NMIJ in Japan.…”

Section: Atomic Fountainsmentioning

confidence: 99%

Lasers, Cold Atoms and Atomic Clocks: Realizing the Second Today

Calonico

2013

EPJ Web of Conferences

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Abstract. The time is the physical quantity that mankind could measure with the best accuracy, thanks to the properties of the atomic physics, as the present definition of time is based on atomic energy transitions. This short review gives some basic information on the heart of the measurement of time in the contemporary world, i.e. the atomic clocks, and some trends related. The atomic secondThe idea to refer the units of measurements to fundamental physics and in particular to quantum physics found its first, and presently the most fruitful application in time and frequency metrology.Considering the quantization of the atomic energy levels and the fundamental Bohr equivalence E = h stating that the difference of two atomic energy level E is proportional to a frequency  by the Planck's constant h, it is straightforward to think of the atom as a possible frequency standard. (AFS) is basically a device composed of a macroscopic oscillator, hereafter Local Oscillator (LO), e.g. a quartz oscillator for a microwave clocks, or a laser for an optical clock, which frequency is directly compared to the frequency of an atomic transition taken as standard, called clock transition. The Cesium iperfine ground transition has been chosen for the definition of the second, and Cesium clocks are also called primary frequency standards. Other kind of atomic clocks exist, based on different atoms and different atomic transitions: there are clocks based on Hydrogen, Rubidium, Mercury, Ytterbium, Strontium, Indium, Aluminum… Once compared to the atomic transition, the frequency of the LO is corrected to match as better as possible the frequency of the reference. EPJ Web of Conferences

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“…This style of measurement, known as Ramsey interferometry, is used in all fountain frequency standards. Much more detailed information can be found in [1][2][3][4].…”

Section: Fountain Frequency Standardsmentioning

confidence: 99%

“…The shifts discussed above are a small subset of possible shifts. More complete discussions can be found in [2,3]. When all known possible shifts have been analyzed and/or measured, an accuracy budget is developed.…”

Section: Frequency Shifts -Systematicmentioning

confidence: 99%

NIST Cesium Fountains - Current Status and Future Prospects

Jefferts¹,

Heavner²,

Parker³

et al. 2007

Acta Phys. Pol. A

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We review the current status of the U.S. Primary Frequency Standard, NIST-F1. NIST-F1 is a laser-cooled cesium fountain based frequency standard with an inaccuracy of less than δf /f ≤ 5×10 −16 ; limited mainly by the radiation field in the room-temperature fountain (blackbody shift). NIST-F1 is one of the best cesium fountains currently contributing to international atomic time, but has reached a point that it is impractical to improve its accuracy substantially. Therefore we are building a new fountain, imaginatively named NIST-F2, with a cryogenic (77 K) Ramsey interrogation zone that lowers the blackbody shift by several orders of magnitude. NIST-F2 is currently undergoing final assembly, and we will discuss our planned (hoped for) performance, which includes frequency inaccuracy of δf /f < 1 × 10 −16 .

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Accuracy evaluation of NIST-F1

Cited by 187 publications

References 27 publications

On the power dependence of extraneous microwave fields in atomic frequency standards

On the power dependence of extraneous microwave fields in atomic frequency standards

Lasers, Cold Atoms and Atomic Clocks: Realizing the Second Today

NIST Cesium Fountains - Current Status and Future Prospects

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