Energy Filament Theory · EFT Full KB
Environmental Decoherence Limits for Ultra-Long-Baseline Entanglement
V33-33.28 · G 判决节 / 审计节 ·
33.28 turns ultra-long-baseline entanglement into a portable degradation court: under one external time-and-frequency reference, only a quality package that falls monotonically with environmental disturbance, settles into an alignable post-threshold plateau across carrier wavelengths and state families, repeats as a near-zero-lag synchrony peak on parallel links, and weakens from near-ground to high-altitude or vacuum-dominated segments can survive; under V08/V09-compatible translation, the common decoherence limit stays an environment-wear / corridor-fidelity ledger in which single-end marginals remain closed rather than a hidden common channel or remote-control verdict.
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Keywords: CHSH S, visibility V, state fidelity F, QBER, PMD, Faraday rotation, group delay, precipitable water vapor, total electron content, optical lattice clock, hydrogen maser, zero-lag co-occurrence, baseline ladder, altitude stratification
Section knowledge units
thesis
33.28 refuses to let any one noisy quantum link masquerade as a universal limit. If a portable decoherence term is real, it should survive across carrier wavelengths, state families, and baseline classes under one external time-and-frequency reference, while ordinary geometry, dispersion, and detector terms are stripped away first. The court therefore asks for a linked package: environmentally monotonic degradation, an alignable post-threshold plateau, same-window synchrony on parallel links, and baseline–altitude layering. That is why the section enters compat adjudication as translate. It may preserve one environment-wear and corridor-fidelity ledger, but it may not let common-limit wording turn into a hidden channel or a remote-communication verdict.
mechanism
The ledger is built from entanglement-quality proxies and alignment discipline. Each link and epoch records graded CHSH S, visibility V, fidelity F, and QBER outputs, then checks whether their direction stays consistent across adjacent sub-bands, two carrier wavelengths, and at least two state families. Environmental drivers such as turbulence strength, precipitable water vapor, total electron content, wind shear, fiber phase-noise spectra, platform vibration, and electromagnetic noise are paired with those quality curves to test for monotonic suppression and a post-threshold plateau. The same chapter also freezes a maximum lag tolerance, scores zero-lag co-occurrence against side-lobes, and compares metropolitan, submarine, near-ground, high-altitude, and space-dominated baseline tiers so altitude ordering can be judged rather than assumed.
mechanism
Execution is single-reference and cross-platform first. Fiber links, near-ground free-space links, and high-altitude or space links are run in parallel under one optical-lattice-clock or hydrogen-maser-grade time-and-frequency anchor, with source and detector conventions frozen before unblinding. Residual upper bounds are built for tropospheric, ionospheric, and fiber terms, measurement teams produce quality-versus-environment curves through at least two cleaning paths and two state families, and environment teams issue sealed prediction cards using only environmental logs, geometry masks, and baseline metadata. Holdout nights, holdout carrier wavelengths, and holdout state families then close the court under cross-institution recomputation, raw-timestamp exchange, and robustness checks against downsampling, added noise, and hardware variation.
evidence
The null suite is designed to break each ordinary explanation separately. PMD, group-delay, and Faraday-rotation perturbations test whether the ranking simply follows dispersive link physics. Gate-width and pump scans expose multi-pair pileup and detector-chain artifacts. Bypass paths and segment on/off toggles ask whether the same “environment dependence” survives even when the target segment is removed. Label permutations and deliberate timebase misalignment should collapse monotonicity and the zero-lag peak toward random if the claim is genuine, while altitude-matched controls test whether vacuum-dominated segments really relax the limit rather than sharing one common-mode detector problem.
boundary
A pass requires the whole package to close at once. At least two platform classes, two institutions, and two carrier wavelengths plus two state families must reproduce environmentally monotonic quality loss with an alignable post-threshold plateau; the ordering must remain non-dispersive rather than following wavelength-squared or inverse-frequency laws; parallel recordings must show a clear near-zero-lag co-occurrence peak; and the limit must tighten near ground while relaxing in higher-altitude or space-dominated segments. Failure is declared if one wavelength, one state family, PMD/group delay, pump/gate choices, or timebase mismatch explains the package better than the sealed environment cards. Multi-pair pileup, timing jitter, and slow polarization or phase drift remain the named systematics that must be bounded before any support claim can stand.
interface
So 33.28 leaves the court only as a translated entanglement protocol. A pass means one portable environment-wear and corridor-fidelity ledger has reproduced across baselines and survived blinding plus nulls. It does not mean a hidden common channel has been uncovered, nor that remote control or superluminal communication has been licensed. Single-end marginals must stay closed. The onward route is into 33.29’s CMB spectral-distortion injection-history court, where residual floor claims face the same feed-forward and falsification discipline.