Probing axion mediated fermion–fermion interaction by means of entanglement

Capolupo, Antonio; Lambiase, Gaetano; Quaranta, Aniello; Giampaolo, Salvatore Marco

doi:10.1016/j.physletb.2020.135407

Cited by 19 publications

(11 citation statements)

References 68 publications

(85 reference statements)

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“…( 2) corresponds to a long-range spin-dependent force among the neutrons. Therefore our analysis well fits within the context of fifth force experiments [33][34][35][36]45,46]. In the following we shall assume that the neutron velocities are non-relativistic and analyze the interaction Hamiltonian (2) within the context of ordinary quantum mechanics.…”

Section: Neutron-neutron Interactionsmentioning

confidence: 54%

“…The results presented in the figure are in the spirit of a model-independent analysis, which in principle applies to any ALP which experiences an interaction with neutrons. Since masses and couplings vary sensibly Notice that the current laboratory constraints on g a N N from fifth force experiments [33][34][35][36]45,46] set an upper bound of the order ∼ 10 −4 . Our setup could in principle improve on such bound.…”

Section: Numerical Analysismentioning

confidence: 99%

“…The latter yields an effective fermionfermion interaction [31,32] in which the ALP plays the role of a mediating boson. For this reason, the detection of ALPs is naturally tied not only to electrodynamics but also to the possibility of experimentally probing interactions between fermions [33][34][35][36]. On the other hand, in the context of neutron physics, interferometry has proven to be a formidable tool in investigating particle interactions and their quantum properties.…”

Section: Introductionmentioning

confidence: 99%

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Neutron interferometry, fifth force and axion like particles

2021

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We propose a new possible detection strategy to reveal the fermion–fermion interaction mediated by axions and axion-like particles, based on interferometric measurement of neutron beams. We consider an interferometer in which the neutron beam is split in two sub-beams propagating in regions with differently oriented magnetic fields. The beam paths and the strength of the magnetic fields are set in such a way that the phase difference depends only on the axion-induced interaction. The resulting phase difference is directly related to the presence of axions. Our results show that such a phase might represent, in the future, a tool to probe the existence of axions and axion-like particles or a fifth force with interferometry.

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Section: Neutron-neutron Interactionsmentioning

confidence: 54%

Section: Numerical Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Neutron interferometry, fifth force and axion like particles

2021

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“…This argument is independent of whether the two Hamiltonians H (1) and H (2) produce distinct observable effects or not. We remark, however, that while the standard oscillation formulae are not affected by the Majorana phase α [3], the latter may well show up in other circumstances, for instance in the propagation in a dissipative medium [4,5] for which the oscillation formulas depend on the Majorana phase. Finally, it is not at all clear why the charged lepton field rephasing should have any effect on neutrinos, which should not be affected by the latter, because then it is obvious that any quantity depending only on the neutrino oscillatory evolution suffers no modification from the charged lepton field rephasing.…”

Section: Arxiv:210708719v1 [Hep-ph] 19 Jul 2021mentioning

confidence: 99%

Geometric phase of neutrinos: Differences between Dirac and Majorana neutrinos

et al. 2018

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“…Here we want to point to a few works, refs. [25,26], where the authors have studied quantum field theory of axion fields and its relation with quantum entanglement.…”

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confidence: 99%

Cosmological Spectrum of Two-Point Correlation Function from Vacuum Fluctuation of Stringy Axion Field in De Sitter Space: A Study of the Role of Quantum Entanglement

Choudhury

Panda

2020

Universe

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In this work, we study the impact of quantum entanglement on the two-point correlation function and the associated primordial power spectrum of mean square vacuum fluctuation in a bipartite quantum field theoretic system. The field theory that we consider is the effective theory of axion field arising from Type IIB string theory compacted to four dimensions. We compute the expression for the power spectrum of vacuum fluctuation in three different approaches, namely (1) field operator expansion (FOE) technique with the quantum entangled state, (2) reduced density matrix (RDM) formalism with mixed quantum state and (3) the method of non-entangled state (NES). For a massless axion field, in all three formalisms, we reproduce, at the leading order, the exact scale invariant power spectrum which is well known in the literature. We observe that due to quantum entanglement, the sub-leading terms for these thee formalisms are different. Thus, such correction terms break the degeneracy among the analysis of the FOE, RDM and NES formalisms in the super-horizon limit. On the other hand, for massive axion field we get a slight deviation from scale invariance and exactly quantify the spectral tilt of the power spectrum in small scales. Apart from that, for massless and massive axion field, we find distinguishable features of the power spectrum for the FOE, RDM, and NES on the large scales, which is the result of quantum entanglement. We also find that such large-scale effects are comparable to or greater than the curvature radius of the de Sitter space. Most importantly, in near future if experiments probe for early universe phenomena, one can detect such small quantum effects. In such a scenario, it is possible to test the implications of quantum entanglement in primordial cosmology.

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Probing axion mediated fermion–fermion interaction by means of entanglement

Cited by 19 publications

References 68 publications

Neutron interferometry, fifth force and axion like particles

Neutron interferometry, fifth force and axion like particles

Geometric phase of neutrinos: Differences between Dirac and Majorana neutrinos

Cosmological Spectrum of Two-Point Correlation Function from Vacuum Fluctuation of Stringy Axion Field in De Sitter Space: A Study of the Role of Quantum Entanglement

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