Phase shift in an atom interferometer induced by the additional laser
  lines of a Raman laser generated by modulation

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Abstract

The use of Raman laser generated by modulation for light-pulse atom interferometer allows to have a laser system more compact and robust. However, the additional laser frequencies generated can perturb the atom interferometer. In this article, we present a precise calculation of the phase shift induced by the additional laser frequencies. The model is validated by comparison with experimental measurements on an atom gravimeter. The uncertainty of the phase shift determination limits the accuracy of our compact gravimeter at 8.10^-8 m/s^2. We show that it is possible to reduce considerably this inaccuracy with a better control of experimental parameters or with particular interferometer configurations.

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Most cited references 8

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Article: not found

Atomic interferometry using stimulated Raman transitions

Mark Kasevich, Steven Chu (1991)

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Precision Rotation Measurements with an Atom Interferometer Gyroscope

T. L. Gustavson, P. Bouyer, M. A. Kasevich (1997)

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Is Open Access

Sensitive Absolute Gravity Gradiometry Using Atom Interferometry

, , … (2001)

We report the demonstration of a sensitive absolute gravity gradiometer based on light-pulse atom interference techniques. The gradiometer consists of two absolute accelerometers operated in a differential mode. We report a differential acceleration sensitivity of 4e-9 g/Hz^(1/2) and an inferred differential acceleration accuracy of less than 1e-9 g. This corresponds to a gravity gradient sensitivity of 4 E/Hz^(1/2) [1 E = 1e-9 s^(-2)] and an accuracy of better than 1 E for a 10 m separation between accelerometers. We demonstrate that the instrument can be used to detect nearby masses in a vibrationally noisy environment and characterize instrument sensitivity to spurious acceleration and rotation noise.