Finite Pulse-Time Effects in Long-Baseline Quantum Clock Interferometry
Abstract
Quantum-clock interferometry has been suggested as a quantum probe to test the universality of free fall (UFF) and the universality of gravitational redshift (UGR). In typical experimental schemes it seems advantageous to employ Doppler-free E1-M1 transitions which have so far been investigated in quantum gases at rest. Here, we consider the fully quantized atomic degrees of freedom and study the interplay of the quantum center-of-mass (COM) that can become delocalized together with the internal clock transitions. In particular, we derive a model for finite-time E1-M1 transitions with atomic intern-extern coupling and arbitrary position-dependent laser intensities. We further provide generalizations to the ideal expressions for perturbed recoilless clock pulses. Finally, we show at the example of a Gaussian laser beam that the proposed quantum-clock interferometers are stable against perturbations from varying optical fields for a sufficiently small quantum delocalization of the atomic COM.
Cite
@article{arxiv.2309.14426,
title = {Finite Pulse-Time Effects in Long-Baseline Quantum Clock Interferometry},
author = {Gregor Janson and Alexander Friedrich and Richard Lopp},
journal= {arXiv preprint arXiv:2309.14426},
year = {2024}
}
Comments
20 pages, 6 figures, V2: updated to match published version