English

Accurate trajectory alignment in cold-atom interferometers with separated laser beams

Atomic Physics 2020-03-13 v2 Instrumentation and Detectors Quantum Physics

Abstract

Cold-atom interferometers commonly face systematic effects originating from the coupling between the trajectory of the atomic wave packet and the wave front of the laser beams driving the interferometer. Detrimental for the accuracy and the stability of such inertial sensors, these systematics are particularly enhanced in architectures based on spatially separated laser beams. Here we analyze the effect of a coupling between the relative alignment of two separated laser beams and the trajectory of the atomic wave packet in a four-light-pulse cold-atom gyroscope operated in fountain configuration. We present a method to align the two laser beams at the 0.2 μ0.2 \ \murad level and to determine the optimal mean velocity of the atomic wave packet with an accuracy of 0.2 mms10.2\ \textrm{mm}\cdot\textrm{s}^{-1}. Such fine tuning constrains the associated gyroscope bias to a level of 1×1010 rads11\times 10^{-10}~\textrm{rad}\cdot\textrm{s}^{-1}. In addition, we reveal this coupling using the point-source interferometry technique by analyzing single-shot time-of-flight fluorescence traces, which allows us to measure large angular misalignments between the interrogation beams. The alignment method which we present here can be employed in other sensor configurations and is particularly relevant to emerging gravitational wave detector concepts based on cold-atom interferometry.

Keywords

Cite

@article{arxiv.1912.04793,
  title  = {Accurate trajectory alignment in cold-atom interferometers with separated laser beams},
  author = {M. Altorio and L. A. Sidorenkov and R. Gautier and D. Savoie and A. Landragin and R. Geiger},
  journal= {arXiv preprint arXiv:1912.04793},
  year   = {2020}
}

Comments

10 pages including appendices, 23 references

R2 v1 2026-06-23T12:41:38.671Z