Measurement of gravitational acceleration by dropping atoms

Peters, A.; Chung, Keng Yeow; Chu, Steven

doi:10.1038/23655

Cited by 870 publications

(957 citation statements)

References 11 publications

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“…The magnetic field necessary to shift adjacent Zeeman sublevels by an amount equal to the vibrational energy splitting is B max Ϸ 140 mG in the center and B min Ϸ 11 mG at the edge of the laser beam. 3 The experimental optimum lies between these upper and lower bounds.…”

Section: A Optimum Magnetic Fieldmentioning

confidence: 99%

“…6. 3 The Zeeman frequency shift of adjacent magnetic sublevels is 350 kHz/ G for the hyperfine ground states of cesium.…”

Section: E Model Of Sideband Raman Cooling In the Lamb-dicke Regimementioning

confidence: 99%

“…Since the discovery of laser cooling [1], beams of slow and cold atoms have played an ever more important role in high-precision experiments-e.g., in atomic interferometry experiments [2,3] and atomic fountain clocks [4]. In this context the continuous beam approach [5] is interesting because it dramatically reduces all undesirable effects of atomic density [4] and the Dick effect which is unavoidable in pulsed beams [6,7].…”

Section: Introductionmentioning

confidence: 99%

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Laser collimation of a continuous beam of cold atoms using Zeeman-shift degenerate-Raman-sideband cooling

et al. 2004

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In this article we report on the use of degenerate-Raman-sideband cooling for the collimation of a continuous beam of cold cesium atoms in a fountain geometry. Thanks to this powerful cooling technique we have reduced the atomic beam transverse temperature from 60 K to 1.6 K in a few milliseconds. The longitudinal temperature of 80 K is not modified. The flux density, measured after a parabolic flight of 0.57 s, has been increased by a factor of 4 to approximately 10 7 at. s −1 cm −2 and we have identified a Sisyphus-like precooling mechanism which should make it possible to increase this flux density by an order of magnitude.

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Section: A Optimum Magnetic Fieldmentioning

confidence: 99%

“…6. 3 The Zeeman frequency shift of adjacent magnetic sublevels is 350 kHz/ G for the hyperfine ground states of cesium.…”

Section: E Model Of Sideband Raman Cooling In the Lamb-dicke Regimementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Laser collimation of a continuous beam of cold atoms using Zeeman-shift degenerate-Raman-sideband cooling

et al. 2004

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“…In particular, atom interferometers are new tools for experimental gravitation as, for example, for precision measurement of gravity acceleration [15], gravity gradients [16], Newtonian gravitational constant G [17], gravity at micrometric distances [18,19], and for testing equivalence principle [20]. The possibility of detecting gravitational waves by atom interferometry was also discussed [21,22].…”

Section: Atom Interferometry Sensors For Space Applicationsmentioning

confidence: 99%

Atom interferometers and optical atomic clocks: New quantum sensors for fundamental physics experiments in space

Tino

Cacciapuoti

Bongs

et al. 2007

Nuclear Physics B - Proceedings Supplements

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“…During the past decades, atom interferometry experiments were developed for various applications like precision measurement of fundamental constants [1,2], gravimetry [3], gradiometry [4] or inertial sensing [5,6]. Based on this methods, cold atoms sensors measure interferometrically the inertial effects affecting the experiment with respect to free falling laser-cooled atoms that are split and recombined using two counter-propagating laser beams.…”

Section: Introductionmentioning

confidence: 99%