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State-of-the-art atom interferometers can keep atoms in a superposition of heights in Earth's gravitational field for times reaching minute-scale, allowing for precise measurements of the gravitational potential. Yet, the phase shifts measured in such experiments can always be explained with a non-relativistic theory of gravity. There is therefore growing interest in finding feasible ways to use such new experimental capabilities to go beyond the non-relativistic regime. Here we propose modifying the existing experimental setups to probe both the quantum and the general relativistic effects on the atom's dynamics. Our proposal consists of adding two additional laser pulses in a trapped atom interferometer that would set up a quantum clock trapped at a superposition of heights reading a quantum superposition of relativistic proper times. We derive the phases acquired by different trajectories in the interferometer and demonstrate that the effect of superposition of proper times would manifest itself in two ways in the interference pattern: as visibility modulations, and as a shift of the resonant frequency of the atom. We argue that the latter might be observable with current technology.
Paczos et al. (Thu,) studied this question.
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