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Mobile and remote inertial sensing with atom interferometers

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Academic year: 2021

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Fig. 1. – (Colour online) (a) Principle of an atom interferometer. An initial atomic wavepacket is split into two parts by a coherent beam-splitting process
Fig. 2. – (Colour online) Three-pulse atom interferometer based on stimulated Raman transi- transi-tions
Fig. 3. – (Colour online) Raman transition energy levels. Atoms initially in the state |1, p ⟩ are transferred to |2, p + ! k eff ⟩ via a two-photon transition from counter-propagating Raman beams.
Table I summarizes the laser phase contributions to the wave function that result from Raman transitions [39]
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