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Quantum Gravity Induced Entanglement of Masses With Extra Dimensions

Published 21 Jul 2023 in gr-qc | (2307.11391v2)

Abstract: It is believed that gravity can be considered as a quantum coherent mediator. In this study, we propose a plan to test the existence of extra dimensions using the Quantum Gravity Induced Entanglement of Masses (QGEM) experiment. This experiment involves two freely falling test masses passing through a Stern-Gerlach-like device. We investigate the entanglement witness between these masses within the framework of the Randall-Sundrum II model (RS-II). Our findings indicate that the system reaches entanglement more rapidly in the presence of extra dimensions, particularly when the radius of the extra dimension is large.

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References (23)
  1. N. Arkani-Hamed, S. Dimopoulos, and G. Dvali, The hierarchy problem and new dimensions at a millimeter, Physics Letters B 429, 263 (1998).
  2. L. Randall and R. Sundrum, Large mass hierarchy from a small extra dimension, Physical review letters 83, 3370 (1999a).
  3. G. Dvali, G. Gabadadze, and M. Shifman, Diluting the cosmological constant in infinite volume extra dimensions, Physical Review D 67, 044020 (2003).
  4. V. Rubakov and M. E. Shaposhnikov, Extra space-time dimensions: towards a solution to the cosmological constant problem, Physics Letters B 125, 139 (1983).
  5. D. E. Kaplan and T. M. Tait, New tools for fermion masses from extra dimensions, Journal of High Energy Physics 2001, 051 (2001).
  6. K. Yoshioka, On fermion mass hierarchy with extra dimensions, Modern Physics Letters A 15, 29 (2000).
  7. S. Raychaudhuri and K. Sridhar, Particle physics of brane worlds and extra dimensions (Cambridge University Press, 2016).
  8. S. K. Rai and S. Raychaudhuri, Single photon signals for warped quantum gravity at a linear e+ e- collider, Journal of High Energy Physics 2003, 020 (2003).
  9. G. F. Giudice, R. Rattazzi, and J. D. Wells, Quantum gravity and extra dimensions at high-energy colliders, Nuclear Physics B 544, 3 (1999).
  10. E. G. Adelberger, B. R. Heckel, and A. E. Nelson, Tests of the gravitational inverse-square law, Annual Review of Nuclear and Particle Science 53, 77 (2003).
  11. C. D. Hoyle, U. Schmidt, B. R. Heckel, E. G. Adelberger, J. H. Gundlach, D. J. Kapner, and H. E. Swanson, Submillimeter test of the gravitational inverse-square law: a search for “large” extra dimensions, Physical Review Letters 86, 1418 (2001).
  12. E. Adelberger, New tests of einstein’s equivalence principle and newton’s inverse-square law, Classical and Quantum Gravity 18, 2397 (2001).
  13. S. G. Elahi and A. Mazumdar, Probing massless and massive gravitons via entanglement in a warped extra dimension (2023), arXiv:2303.07371 [gr-qc] .
  14. P. Li, Y. Ling, and Z. Yu, Generation rate of quantum gravity induced entanglement with multiple massive particles, Physical Review D 107, 064054 (2023).
  15. A. Matsumura and K. Yamamoto, Gravity-induced entanglement in optomechanical systems, Physical Review D 102, 106021 (2020).
  16. A. Großardt, Acceleration noise constraints on gravity-induced entanglement, Phys. Rev. A 102, 040202 (2020).
  17. L. Randall and R. Sundrum, An alternative to compactification, Physical Review Letters 83, 4690 (1999b).
  18. J. Garriga and T. Tanaka, Gravity in the randall-sundrum brane world, Physical Review Letters 84, 2778 (2000).
  19. S. B. Giddings, E. Katz, and L. Randall, Linearized gravity in brane backgrounds, Journal of High Energy Physics 2000, 023 (2000).
  20. N. Deruelle and T. Doležel, Linearized gravity in the randall-sundrum scenario, Physical Review D 64, 103506 (2001).
  21. R. Maartens and K. Koyama, Brane-world gravity, Living Reviews in Relativity 13, 1 (2010).
  22. M. Christodoulou and C. Rovelli, On the possibility of laboratory evidence for quantum superposition of geometries, Physics Letters B 792, 64 (2019).
  23. L. Stodolsky, Matter and light wave interferometry in gravitational fields, General Relativity and Gravitation 11, 391 (1979).
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