A theoretical framework, The Silence Paradigm, proposing that the role of the conscious observer in quantum measurement can be treated as a controlled experimental variable and tested at the quantum–classical boundary. The framework treats the observer's cognitive state as a variable that may produce measurable shifts in decoherence time (T₂) and develops the theoretical case for testing this against the prevailing environmental decoherence framework (Zurek, Zeh, Joos). The framework's primary prediction is specific and falsifiable: T₂ at the two deepest accessible consciousness conditions, C7 (Cessation / Objectless Awareness) and C6 (Minimal Phenomenal Experience) will exceed T₂ at chamber baseline and at the five other consciousness conditions (C1–C5), with the largest effect at C7. The companion paper, The Silence Experiment operationalises this as two pre-registered orthogonal planned contrasts with directional predictions and details the seven-condition protocol, shielded chamber design, and pre-registered statistical framework. The framework is most closely aligned with a modified von Neumann–Wigner interpretation, grounded in contemplative phenomenology (Lutz et al., 2004; Metzinger, 2020) and producing empirically testable predictions. It does not build on positive claims from prior consciousness–RNG research; one explicit goal is to resolve the inconsistency of that literature through improved controls, EEG-verified cognitive states, and pre-registered analysis. This framework is proposed as a hypothesis-generating structure, not as established theory. Null results establish pre-registered upper bounds; positive results require independent replication on different hardware, in a different facility, before claims can be considered established.
Clifton Bacon (Wed,) studied this question.