Measurement of Anomalous Forces From a Cooper-Pair Current in High-Tc Superconductors With Nano-Newton Precision

Neunzig, O.; Kößling, Matthias

doi:10.3389/fphy.2022.892215

Cited by 4 publications

(3 citation statements)

References 21 publications

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“…• The gravito-magnetic field, B G , is expelled from a superconductor in a Meissner effect only if there is also a magnetic field satisfying B < − B G (m e /e). This observation is being taken into account for guiding experimental work [101]. The associated penetration depth is found in Eq.…”

Section: Discussionmentioning

confidence: 99%

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Superconductor Meissner Effects for Gravito-Electromagnetic Fields in Harmonic Coordinates Due to Non-Relativistic Gravitational Sources

Inan

2022

Front. Phys.

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There is much discrepancy in the literature concerning the possibility of a superconductor expelling gravito-electromagnetic fields just as it expels electromagnetic fields in the Meissner effect. Contradicting results are found in at least 18 papers written collectively by more than 20 authors and published over the course of more than 55 years (from 1966 to the present year of 2022). The primary purpose of this paper is to carefully explain the reason for the discrepancies, and provide a single conclusive treatment which may bring coherence to the subject. The analysis begins with a covariant Lagrangian for spinless charged particles (Cooper pairs) in the presence of electromagnetic fields in curved space-time. It is known that such a Lagrangian can lead to a vanishing Hamiltonian. Alternatively, it is shown that using a “space + time” Lagrangian leads to an associated Hamiltonian with a canonical momentum and minimal coupling rule. Discrepancies between Hamiltonians obtained by various authors are resolved. The canonical momentum leads to a modified form of the London equations and London gauge that includes the effects of gravity. A key result is that the gravito-magnetic field is expelled from a superconductor with a penetration depth on the order of the London penetration depth only when an appropriate magnetic field is also present. The gravitational flux quantum (fluxoid) in the body of a superconductor, and the quantized supercurrent in a superconducting ring, are also derived. Lastly, the case of a superconducting ring in the presence of a charged rotating mass cylinder is used as an example of applying the formalism developed.

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Section: Discussionmentioning

confidence: 99%

“…Therefore, it is found that B G is expelled from the superconductor with a penetration depth on the order of the London penetration depth, provided a magnetic field is also present. This observation is being taken into account for guiding experimental work [101].…”

Section: The Effect Of B On the Penetration Depth Of B Gmentioning

confidence: 99%

Superconductor Meissner Effects for Gravito-Electromagnetic Fields in Harmonic Coordinates Due to Non-Relativistic Gravitational Sources

Inan

2022

Front. Phys.

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“…However, the presence of such 'strange' gravitomagnetic fields would be at odds with known properties of compact objects, such as neutron stars [142]. In addition, a recent work by Tajmar et al [143] imposes narrower constraints on the impact of gravitomagnetic effects on the explanation of anomalous Cooper pair mass excess.…”

Section: Laboratory Testsmentioning

confidence: 99%

A tale of analogies: a review on gravitomagnetic effects, rotating sources, observers and all that

Ruggiero,

Astesiano

2023

J. Phys. Commun.

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Gravitoelectromagnetic analogies are somewhat ubiquitous in General Relativity, and they are often used to explain peculiar effects of Einstein's theory of gravity in terms of familiar results from classical electromagnetism. Perhaps, the best known of these analogy pertains to the similarity between the equations of electromagnetism and those of the linearized theory of General Relativity. But the analogy is somewhat deeper and ultimately rooted in the splitting of spacetime, which is preliminary to the definition of the measurement process in General Relativity.In this paper we review the various approaches that lead to the introduction of a magnetic-like part of the gravitational interaction, briefly called \textit{gravitomagnetic} and, then, we provide a survey of the recent developments both from the theoretical and experimental viewpoints.

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Exergy and exergoeconomic analysis of a hybrid airborne wind and solar energy system for power, liquid nitrogen and carbon dioxide production

Nouri,

Kavgic,

Hinzer

et al. 2024

Energy Reports

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Measurement of Anomalous Forces From a Cooper-Pair Current in High-Tc Superconductors With Nano-Newton Precision

Cited by 4 publications

References 21 publications

Superconductor Meissner Effects for Gravito-Electromagnetic Fields in Harmonic Coordinates Due to Non-Relativistic Gravitational Sources

Superconductor Meissner Effects for Gravito-Electromagnetic Fields in Harmonic Coordinates Due to Non-Relativistic Gravitational Sources

A tale of analogies: a review on gravitomagnetic effects, rotating sources, observers and all that

Exergy and exergoeconomic analysis of a hybrid airborne wind and solar energy system for power, liquid nitrogen and carbon dioxide production

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