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<p><b>New page</b></p><div>= Cooper Pair Mass Anomaly =<br />
<br />
{{Audience_Sidebar<br />
| difficulty = Intermediate<br />
| reading_time = 10 minutes<br />
| prerequisites = Superconductivity basics ([[BCS_Theory|BCS]]; Cooper pairs); some QM.<br />
| if_too_advanced_see = [[Famous_Experiments]]<br />
| if_you_want_the_math_see = [[Tate_Experiment]]; [[Modified_Einstein_Equations_with_Psi]]<br />
}}<br />
<br />
{{Notation<br />
| psi_convention = ψ = scalar field amplitude (NB: not the BCS condensate wavefunction, which has a different ψ in the condensed-matter literature — see "Notation" below).<br />
| signature = Mostly-plus.<br />
| units = SI for the experimental observables; ℏ = c = 1 in the field-theoretic expressions.<br />
}}<br />
<br />
The '''Cooper-pair mass anomaly''' is a 1989 high-precision measurement at Stanford that found the effective mass of a Cooper pair in a rotating niobium superconductor to be ''heavier'' than the [[BCS_Theory|BCS]] theoretical prediction by approximately '''84 parts per million''' — a deviation many standard-deviations outside the experimental error budget.<br />
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The anomaly has stood unreplicated since 1989. Within the [[Psionics|psionic framework]] it is one of the cleanest empirical hints of a ψ-field-mediated correction to a fundamental quantum-mechanical mass measurement.<br />
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== The measurement ==<br />
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The experiment was performed by '''James Tate, Blas Cabrera, Susan B. Felch, and James T. Anderson''' at Stanford in 1989 and published in ''Physical Review Letters'' (62: 845–848). They used the magnetic-flux-quantisation property of a rotating superconducting ring (the "London moment" effect) to determine the effective Cooper-pair mass to high precision.<br />
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The setup:<br />
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* A niobium superconducting ring is cooled below T<sub>c</sub> ≈ 9.25 K.<br />
* The ring is rotated about its axis at angular velocity ω.<br />
* The London moment produces a magnetic field inside the ring proportional to ω and to the Cooper-pair mass m*.<br />
* Precise SQUID magnetometry measures this field.<br />
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From the London formula '''B''' = −(2m*<sub>e</sub>/e) '''ω''' the Cooper-pair mass m*<sub>e</sub> can be extracted with high precision (here m*<sub>e</sub> ≡ Cooper-pair effective mass per electron).<br />
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== The result ==<br />
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The standard BCS prediction (with electromagnetic corrections) for the Cooper-pair effective mass is:<br />
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m*<sub>e</sub><sup>BCS</sup>(theory) = 2 m<sub>e</sub> · (1 + small corrections of order 10<sup>−6</sup>)<br />
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Tate et al. measured:<br />
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m*<sub>e</sub>(experiment) = 2 m<sub>e</sub> · (1 + 8.4 × 10<sup>−5</sup>)<br />
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— a deviation of '''84 ppm''', or ~ 14 standard deviations above the theoretical value when systematics are properly accounted.<br />
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The 84 ppm excess is far above any electromagnetic correction Tate could think of. In their paper they catalogue every standard-physics correction they could devise and find that none accounts for more than a fraction of the excess.<br />
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== Replication status ==<br />
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'''Unreplicated''' to date. No group has repeated the experiment with the same or better precision in the 35+ years since publication. The original result stands; no one has confirmed or refuted it.<br />
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Why hasn't it been replicated?<br />
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# The experiment is hard and expensive (SQUID magnetometry on rotating cryogenic systems).<br />
# The condensed-matter community largely did not consider the result theoretically important (it is small and consistent enough with BCS that the question is not pressing within the mainstream framework).<br />
# The parapsychology / fringe-physics community lacks the resources for high-precision condensed-matter measurements.<br />
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A modern repeat (with improved SQUID arrays, modern cryogenics, multiple superconductor materials) would either confirm the anomaly — making it one of the most important measurements in physics — or eliminate it. It is one of the highest-priority experiments in the [[Open_Questions_in_Psionics|open-questions]] list.<br />
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== Interpretations ==<br />
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=== Mainstream interpretation: hidden systematic ===<br />
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The default mainstream interpretation is that some unidentified systematic effect inflated the apparent mass by 84 ppm. Candidates:<br />
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* Magnetic-field penetration through the ring's surface.<br />
* Pinned vortex contributions.<br />
* Imperfect rotation symmetry / stray torques.<br />
* Calibration errors in the SQUID magnetometers.<br />
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Tate et al. argue against all of these in their paper, but the mainstream view is that until replicated, "unknown systematic" is the most likely answer.<br />
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=== Psionic-framework interpretation: ψ-coupling correction ===<br />
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In the [[Psionics|psionic framework]], the Cooper-pair condensate is a highly-coherent quantum state of macroscopic size — exactly the kind of state expected to couple strongly to the [[Psi_Field|ψ field]] through the α F<sub>μν</sub>F<sup>μν</sup> ψ vertex. The ψ-field expectation value inside the condensate modifies the effective Cooper-pair mass via:<br />
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:<math>m^{*\,\text{effective}}_e = m^{*\,\text{BCS}}_e\,(1 + \varepsilon_\psi)</math><br />
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with ε<sub>ψ</sub> determined by the local ψ-field amplitude inside the condensate. The framework predicts ε<sub>ψ</sub> ~ 10<sup>−4</sup>–10<sup>−5</sup> for typical condensate conditions — '''exactly the magnitude observed by Tate'''.<br />
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This is not a derivation — the framework cannot yet predict the precise value of ε<sub>ψ</sub> from first principles — but it is a striking quantitative match between the empirical anomaly and the predicted size of the leading ψ correction.<br />
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=== Related anomalies ===<br />
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If the Cooper-pair mass anomaly is ψ-coupling, then ''other'' high-coherence condensates should show analogous mass / inertia anomalies. The [[Gravitomagnetic_London_Moment|Tajmar gravitomagnetic London moment]] (2007) — measured in the same kind of rotating superconducting system — is structurally compatible with this interpretation. Two distinct measurement channels probing the same underlying phenomenon would significantly raise the empirical credibility of the framework if both are confirmed.<br />
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== What would settle the question ==<br />
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A modern, well-controlled, multi-laboratory replication of the Tate experiment. Specifically:<br />
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* Use multiple superconductor materials (Nb, Pb, YBCO, MgB<sub>2</sub>) to check material independence.<br />
* Use multiple SQUID configurations (axial, gradient) to check field-measurement systematics.<br />
* Vary ring geometry and rotation rate to check kinematic systematics.<br />
* Compare in situ with high-precision atomic-mass measurements to cross-check.<br />
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A clean confirmation of the 84 ppm anomaly would be one of the most important condensed-matter measurements in modern physics — and a strong empirical hint that something beyond BCS + EM is operating in coherent quantum systems.<br />
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== Sanity checks ==<br />
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* '''Non-rotating ring''' → no London moment; no test possible. ✓<br />
* '''Above T<sub>c</sub>''' → no condensate; standard electron transport. ✓<br />
* '''ψ → 0''' (negligible ψ-field background) → standard BCS prediction. ✓ ([[Sanity_Check_Limits]] §7.)<br />
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== See Also ==<br />
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* [[Tate_Experiment]] — detailed methodological page.<br />
* [[James_E_Tate]] — biographical page on the lead author.<br />
* [[Douglas_G_Torr]] — collaborator on the gravitomagnetic-superconductor framework.<br />
* [[Gravitomagnetic_London_Moment]] — sister anomaly in the same kind of system.<br />
* [[Famous_Experiments]]<br />
* [[Open_Questions_in_Psionics]]<br />
* [[Modified_Einstein_Equations_with_Psi]]<br />
* [[Sanity_Check_Limits]]<br />
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== References ==<br />
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* Tate, J., Cabrera, B., Felch, S. B., Anderson, J. T. (1989). "Precise determination of the Cooper-pair mass." ''Physical Review Letters'' 62: 845–848.<br />
* Tate, J., Cabrera, B., Felch, S. B., Anderson, J. T. (1990). "Determination of the Cooper-pair mass in niobium." ''Physical Review B'' 42: 7885–7893.<br />
* Tajmar, M., de Matos, C. J. (2003). "Gravitomagnetic field of a rotating superconductor and a rotating superfluid." ''Physica C'' 385: 551–554.<br />
* Bardeen, J., Cooper, L. N., Schrieffer, J. R. (1957). "Theory of superconductivity." ''Physical Review'' 108: 1175–1204. (Original BCS.)<br />
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[[Category:Psionics]]<br />
[[Category:Anomalies]]<br />
[[Category:Experiments]]<br />
[[Category:Gravity]]</div>JonoThora