A clock network for geodesy and fundamental science

Lisdat, Ch.; Grosche, G.; Quintin, Nicolas; Shi, Chunyan; Raupach, S. M. F.; Grebing, Christian; Nicolodi, Daniele; Stefani, Fabio; Al-Masoudi, A.; Dörscher, S.; Häfner, Sebastian; Robyr, Jean-Luc; Chiodo, N.; Bilicki, S.; Bookjans, Eva; Koczwara, A.; Koke, Sebastian; Kühl, Alexander; Wiotte, Fabrice; Meynadier, Frédéric; Camisard, Émilie; Abgrall, M.; Lours, M.; Legero, Thomas; Schnatz, H.; Sterr, U.; Denker, Heiner; Chardonnet, Ch.; Coq, Yann Le; Santarelli, Giorgio; Amy‐Klein, Anne; Targat, Rodolphe Le; Lodewyck, Jérôme; Lopez, Olivier; Pottie, Paul-Eric

doi:10.1038/ncomms12443

Cited by 357 publications

(282 citation statements)

References 43 publications

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“…Table 1 shows the uncertainty budget for the 171 Yb optical lattice frequency standard. The fractional uncertainty for the measurement reported here is 1.5 10 16 × − . The contributions of the systematic effects will be discussed below.…”

Section: Clock Operationmentioning

confidence: 80%

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Absolute frequency measurement of the ${{}^{1}}{{\text{S}}_{0}}$ – ${{}^{3}}{{\text{P}}_{0}}$ transition of¹⁷¹Yb

et al. 2017

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We report the absolute frequency measurement of the unperturbed transition S 1 0 -P 3 0 at 578 nm in 171 Yb realized in an optical lattice frequency standard relative to a cryogenic caesium fountain. The measurement result is 518 295 836 590 863.59(31) Hz with a relative standard uncertainty of 5.9 10 16 × − . This value is in agreement with the ytterbium frequency recommended as a secondary representation of the second in the International System of Units.

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Section: Clock Operationmentioning

confidence: 80%

“…In the low density regime ITCsF2 contributes to an uncertainty of 3.0 10 16 × − with a stability of 3.6 10 s…”

Section: Absolute Frequency Measurementmentioning

confidence: 99%

Absolute frequency measurement of the ${{}^{1}}{{\text{S}}_{0}}$ – ${{}^{3}}{{\text{P}}_{0}}$ transition of¹⁷¹Yb

et al. 2017

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“…For this purpose, optical time transfer via SLR will play an important role. In an environment, where major national standards laboratories currently develop highly accurate two-way frequency comparison techniques, in order to compare the frequency of optical clocks over distances of thousands of km (Lisdat et al 2016), laser time transfer by SLR techniques can be a valuable extension on the route to extend the coherence of time over larger distances on the ground and also into the near Earth orbit. Precise clocks in space like those of the ACES project are very suitable candidates for this purpose.…”

Section: Discussionmentioning

confidence: 99%

The Application of Coherent Local Time for Optical Time Transfer and the Quantification of Systematic Errors in Satellite Laser Ranging

Kodet

2017

Space Sci Rev

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Highly precise time and stable reference frequencies are fundamental requirements for space geodesy. Satellite laser ranging (SLR) is one of these techniques, which differs from all other applications like Very Long Baseline Interferometry (VLBI), Global Navigation Satellite Systems (GNSS) and finally Doppler Orbitography and Radiopositioning Integrated by Satellite (DORIS) by the fact that it is an optical two-way measurement technique. That means that there is no need for a clock synchronization process between both ends of the distance covered by the measurement technique. Under the assumption of isotropy for the speed of light, SLR establishes the only practical realization of the Einstein Synchronization process so far. Therefore it is a powerful time transfer technique. However, in order to transfer time between two remote clocks, it is also necessary to tightly control all possible signal delays in the ranging process. This paper discusses the role of time and frequency in SLR as well as the error sources before it address the transfer of time between ground and space. The need of an improved signal delay control led to a major redesign of the local time and frequency distribution at the Geodetic Observatory Wettzell. Closure measurements can now be used to identify and remove systematic errors in SLR measurements.

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“…There are two main reasons for this. Atomic physics experiments can reach incredibly high accuracy (for example, clock synchronization at levels of a few 10 −17 [61] and 10 −18 [62] of relative accuracy), and have several control parameters which, for instance, allow one to isolate and measure individual relativistic terms by using their scalings with these parameters.…”

Section: Fundamental Physics and Quantum Tests Of Weak Equivalence Prmentioning

confidence: 99%

Inertial quantum sensors using light and matter

2016

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Abstract. The past few decades have seen dramatic progress in our ability to manipulate and coherently control matter-waves. Although the duality between particles and waves has been well tested since de Broglie introduced the matter-wave analog of the optical wavelength in 1924, manipulating atoms with a level of coherence that enables one to use these properties for precision measurements has only become possible with our ability to produce atomic samples exhibiting temperatures of only a few millionths of a degree above absolute zero. Since the initial experiments a few decades ago, the field of atom optics has developed in many ways, with both fundamental and applied significance. The exquisite control of matter waves offers the prospect of a new generation of force sensors exhibiting unprecedented sensitivity and accuracy, for applications from navigation and geophysics to tests of general relativity. Thanks to the latest developments in this field, the first commercial products using this quantum technology are now available. In the future, our ability to create large coherent ensembles of atoms will allow us an even more precise control of the matter-wave and the ability to create highly entangled states for non-classical atom interferometry.

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A clock network for geodesy and fundamental science

Cited by 357 publications

References 43 publications

Absolute frequency measurement of the ${{}^{1}}{{\text{S}}_{0}}$ – ${{}^{3}}{{\text{P}}_{0}}$ transition of¹⁷¹Yb

Absolute frequency measurement of the ${{}^{1}}{{\text{S}}_{0}}$ – ${{}^{3}}{{\text{P}}_{0}}$ transition of¹⁷¹Yb

The Application of Coherent Local Time for Optical Time Transfer and the Quantification of Systematic Errors in Satellite Laser Ranging

Inertial quantum sensors using light and matter

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A clock network for geodesy and fundamental science

Cited by 357 publications

References 43 publications

Absolute frequency measurement of the ${{}^{1}}{{\text{S}}_{0}}$ – ${{}^{3}}{{\text{P}}_{0}}$ transition of171Yb

Absolute frequency measurement of the ${{}^{1}}{{\text{S}}_{0}}$ – ${{}^{3}}{{\text{P}}_{0}}$ transition of171Yb

The Application of Coherent Local Time for Optical Time Transfer and the Quantification of Systematic Errors in Satellite Laser Ranging

Inertial quantum sensors using light and matter

Contact Info

Product

Resources

About

Absolute frequency measurement of the ${{}^{1}}{{\text{S}}_{0}}$ – ${{}^{3}}{{\text{P}}_{0}}$ transition of¹⁷¹Yb

Absolute frequency measurement of the ${{}^{1}}{{\text{S}}_{0}}$ – ${{}^{3}}{{\text{P}}_{0}}$ transition of¹⁷¹Yb