Proposal for a Bell Test with Entangled Atoms of Different Mass

• URL: http://arxiv.org/abs/2411.08356v1
• Date: Wed, 13 Nov 2024 06:00:01 GMT
• Title: Proposal for a Bell Test with Entangled Atoms of Different Mass
• Authors: X. T. Yan, S. Kannan, Y. S. Athreya, A. G. Truscott, S. S. Hodgman,
• Abstract summary: We propose an experimental scheme for performing a Bell test using momentum-entangled pairs of atoms with different masses. We use the metastable isotopes of helium 3He* and 4He* for their single-atom detection capabilities. The entangled state is generated by colliding these species and manipulated via two independent atom interferometers.
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• Abstract: We propose an experimental scheme for performing a Bell test using momentum-entangled pairs of atoms with different masses. This proposal uses the metastable isotopes of helium 3He* and 4He* for their single-atom detection capabilities, though the approach could be generalised to other atoms. The entangled state is generated by colliding these species and manipulated via two independent atom interferometers. This method enables precise control of the relative phases of each species, overcoming previous challenges in single-species atomic momentum Bell tests. Numerical simulations of the process show that it should be possible to achieve a significant violation of Bell's inequality under realistic experimental conditions and within a quantum mechanics framework. This type of superposition is interesting from a general relativity perspective as it introduces ambiguity in determining spacetime curvature of the quantum state. Such experiments are necessary to better understand the intersection between quantum mechanics and gravity.

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