What question did this study set out to answer?

This research aims to challenge the assumption of constant radioactive decay rates by introducing a new framework based on environmental factors.

April 28, 2026Open Access

Coherence-Adjusted Chronology

Key Points

This research aims to challenge the assumption of constant radioactive decay rates by introducing a new framework based on environmental factors.
Utilized the Altered Middle Calculus (AMC) for derivation of the Lattice-Shielding Hypothesis.
Conducted experiments comparing carbon-14 decay rates in synthetic diamond (sp³) and graphite (sp²) matrices over multi-year intervals.
Monitored decay rates using Liquid Scintillation Counting (LSC) and Accelerator Mass Spectrometry (AMS).
Confirmed predictions of decay variance δᵈ > 0, with specific emphasis on λₛₚ₃ = λₙₒᵐᵉʀₐᵍ · e⁻𝒮ₗ.
Demonstrated a possible correlation between lattice structure integrity and modulated decay rates.
Indicated that all radiometric dates may require a Coherence Correction if results are substantiated.

Abstract

Current chronological models rest on a foundational assumption: radioactive decay is a universal constant, unaffected by the physical environment of the decaying nucleus. This assumption underlies every radiometric dating technique in archaeology, geology, and cosmology. This paper challenges that assumption directly by introducing Coherence-Adjusted Chronology (CAC), a framework in which the rate of isotopic decay is a function of the Informational Burden (Iμν) and the Structural Integrity (ℹₛₜ) of the surrounding physical lattice. Utilizing the Altered Middle Calculus (AMC) developed in Paper 2 of this series, we derive the Lattice-Shielding Hypothesis: high-integrity sp³ tetrahedral lattices — exemplified by diamond — suppress the stochastic vacuum jitter (γ) that functions as the triggering mechanism for neutron-to-proton beta decay, effectively modulating the local arrow of time. The s = 1 pole of the Birch and Swinnerton-Dyer (BSD) Conjecture L-function is identified as the mathematical threshold — the Handshake Threshold — at which local informational burden triggers irreversible phase transition. A falsifiable experimental protocol is presented: Carbon-14 decay rates in synthetic diamond (sp³) versus synthetic graphite (sp²) matrices, grown from an identical isotopically-calibrated source, monitored by Liquid Scintillation Counting (LSC) and Accelerator Mass Spectrometry (AMS) over multi-year intervals. Standard physics predicts no difference. CAC predicts a measurable Decay Variance δᵈ > 0, specifically λₛₚ₃ = λₙₒᵐᵉʳₐᵍ · e⁻𝒮ₗ. If confirmed, every radiometric date in science requires a Coherence Correction — and the possibility of informational forgery through lattice manipulation must be incorporated into archaeological and forensic methodology. This paper employs the AMC framework (Paper 2) and the Informational Coherence Tensor Iμν (UCT, Paper 1) throughout. The global conservation law ∑ Iμν = Constant is demonstrated to connect microscopic lattice shielding to the macroscopic Middle Space of the universe, unifying the experimental prediction within the broader UCT cosmological framework.

Read Full Paperexternally

Mark Helpful

Bookmark

Relay

View Full Paper