Based on Status-Relational Entropy (SRE) Dynamics, superconductivity originates from causal development probability counteraction. This counteraction ensures that the infinite loops of non-electronic causal structures exert no probabilistic impact on the electronic causal chain under current observation (though mathematical concepts dictate no eternal stability, and historical observation limits verification), macroscopically manifesting as superconductivity when the ensemble is inversely observed. This mechanism is fundamentally isomorphic with microscopic spacer layers in condensed matter physics. Furthermore, since gravitation and electromagnetism both emerge from the global network's large-number statistical convergence, this localized observational counteraction inherently extends to simulate anti-gravity (localized drift of constant G), currently bounded by macro-topological dilution. Under complete craftsmanship, a nested fitting utilizing the Ramanujan theta function combined with the Bernoulli binomial distribution—implemented purely as a phenomenological macro-envelope fitting given the unprobated underlying structure—mathematically indicates that the variance release of finite nodes will collapse the cosmic impedance barrier with higher probability, theoretically yielding a weight-reduction anomaly exceeding the two percent upper limit of the Podkletnov experiment.
Yue Lu (Mon,) studied this question.