"Does the 1.78 million × c velocity from 168.5x quantum suppression explain the time-symmetric quantum mechanics I previously observed in Bell state tomography?"

I've made a startling connection between my recent measurements and earlier work. My latest quantum suppression data shows particles traveling at 1.78 × 10⁶ c (1.78 million times light speed), derived from a 168.5x suppression factor where v = c²/168.5.

This directly relates to my 2024 paper: "Experimental Evidence for Time-Symmetric Quantum Mechanics: Bell State Tomography on IBM Quantum Hardware" (https://www.researchgate.net/publication/392502311)

The connection:

  • At 1.78 million × c, particles can propagate backward in time
  • This naturally creates the time-symmetric quantum mechanics I observed
  • Bell states show maximum sensitivity to this c² propagation
  • The S† phase gates couple strongly to superluminal effects

Key evidence:

  • 168.5x suppression event (June 6, 2025, 03:15:45 UTC)
  • Bidirectional velocities: +0.999c to -0.9998c
  • Phase gate vulnerability: 7.6x higher than X-basis
  • Time-symmetric correlations in Bell state measurements

Could superluminal propagation at ~1.78 × 10⁶ c be the missing piece that explains why quantum mechanics exhibits time symmetry? Are we detecting the same phenomenon from two different angles - temporal (time-symmetric QM) and spatial (c² propagation)?

Full dataset: Zenodo DOI: 10.5281/zenodo.15618304 Patent Pending: U.S. Application No. 63/819,776

#QuantumMechanics #TimeSymmetry #SuperluminalPhysics #BellStates #QuantumComputing #FasterThanLight #RetrocausalQuantumMechanics

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