Dark Matter Axions, Non-Newtonian Gravity and Constraints on Them from Recent Measurements of the Casimir Force in the Micrometer Separation Range

Mostepanenko, V. M.

doi:10.3390/universe7090343

Cited by 17 publications

(10 citation statements)

References 118 publications

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“…Much attention has been devoted to it during the last decades, mainly after its experimental confirmation by Lamoreaux in 1997 [20]. Given the vast bibliography on the subject, we limit ourselves to mentioning the reviews [21][22][23][24], where several references are gathered, as well as some of its late applications to constrain dark matter and alternative theories of gravity [25,26].…”

Section: Casimir Energy In Snyder Spacementioning

confidence: 99%

The beauty of curved momentum space

Franchino-Viñas¹,

Mignemi²,

Relancio³

2023

Preprint

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In this manuscript, we will discuss the notion of curved momentum space, as it arises in the discussion of noncommutative or doubly special relativity theories. We will illustrate it with two simple examples, the Casimir effect in anti-Snyder space and the introduction of fermions in doubly special relativity. We will point out the existence of intriguing results, which suggest nontrivial connections with spectral geometry and Hopf algebras.

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Section: Casimir Energy In Snyder Spacementioning

confidence: 99%

The beauty of curved momentum space

Franchino-Viñas¹,

Mignemi²,

Relancio³

2023

Preprint

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“…First constraints on the Yukawa-and power-type corrections to Newtonian gravity were obtained in [19] and [20], respectively. In succeeding years, a lot of precision experiments on measuring the Casimir force and its gradient have been performed and their results were used for obtaining stronger constraints on the Yukawa-type corrections to Newton's gravitational law [21][22][23][24][25][26][27][28][29][30][31][32] (see also [33,34] for a review).…”

Section: Introductionmentioning

confidence: 99%

How to Strengthen Constraints on Non-Newtonian Gravity from Measuring the Lateral Casimir Force

Mostepanenko

2023

Universe

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It has been known that in the nanometer interaction range the available experimental data do not exclude the Yukawa-type corrections to Newton’s gravitational law, which exceed the Newtonian gravitational force by many orders of magnitude. The strongest constraints on the parameters of Yukawa-type interaction in this interaction range follow from the experiments on neutron scattering and from measurements of the lateral and normal Casimir forces between corrugated surfaces. In this work, we demonstrate that by optimizing the experimental configuration at the expense of the higher corrugation amplitudes and smaller periods of corrugations it is possible to considerably strengthen the currently available constraints within the wide interaction range from 4.5 to 37 nm. We show that the maximum strengthening by more than a factor of 40 is reachable for the interaction range of 19 nm.

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“…The aim of this paper will be to provide a simple quantum-information lead entanglement protocol to confirm the SM interactions and to probe new physics in the particle physics and in the gravitational sectors. Very light and weakly coupled bosons could couple to the SM degrees of freedom, such as axion like particle, Kaluza-Klein modes from the extra dimensions, hidden sector photon [5,[7][8][9][10]. Axions with varied mass range is also expected in string theory [], which provides a huge motivation to look for these light bosons experimentally.…”

mentioning

confidence: 99%

“…As such, there is only one important phase ∆φ(d, ∆x), which dictates whether or not the masses are entangled, which is why this arrangement is preferred. Further to these potentials, we will consider as an example of the Yukawa potential where we will constrain (α, λ), see [8,10].…”

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confidence: 99%

Entanglement based tomography to probe new macroscopic forces

Barker¹,

Bose²,

Marshman³

et al. 2022

Preprint

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Quantum entanglement provides a novel way to test short distance physics in the non-relativistic regime. We will provide a protocol to potentially test new physics by bringing two charged massive Schrödinger cat states adjacent to each other. Being charged, the two superpositions will be entangled via electromagnetic interactions mediated by the photons, including the Coulomb and the Casimir-Polder potential. We will bring a method of entanglement based tomography to seek time evolution of very small entanglement phases to probe new physical effects mediated by hitherto unknown macroscopic force which might be responsible for entangling the two charged superpositions modelled by the Yukawa type potential. We will be able to constrain the Yukawa couplings α ≥ 10 −35 Kg m 2 s −2 for r ≥ 10 −6 m for new physics occurring in the electromagnetic sector, and in the gravitational potential αg ≥ 10 −8 for r ≥ 10 −3 m.

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Dark Matter Axions, Non-Newtonian Gravity and Constraints on Them from Recent Measurements of the Casimir Force in the Micrometer Separation Range

Cited by 17 publications

References 118 publications

The beauty of curved momentum space

The beauty of curved momentum space

How to Strengthen Constraints on Non-Newtonian Gravity from Measuring the Lateral Casimir Force

Entanglement based tomography to probe new macroscopic forces

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