Current Publications

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 A Unified Information-Differentiation Framework for Emergent Dimensional Projection and Conscious Experience, with Preliminary Quantum Simulation Results:  What if consciousness isn’t receiving reality, but generating it? Consciousness Field Theory (CFT) introduces a novel framework where consciousness emerges from self-referential information differentiation, driving the very projection of dimensional space itself. By unifying quantum mechanics, information theory, and relativity, CFT models consciousness as an active operator shaping observable reality through entropy-driven projection collapse. This paper presents preliminary quantum simulation results performed on IBM Quantum Cloud, revealing the predicted entropy-gradient instabilities as informational complexity scales. The findings provide early experimental signals supporting the theory’s key predictions and open new interdisciplinary pathways for testing consciousness as a physically emergent phenomenon. 

 What holds a conscious-like state together? This study introduces the Kilgore Field Equation (KFE), a nonlinear, noisy field model where continuity emerges when information differentiates within itself. Two complementary formulations (diffusive–reactive and damped-wave) are tested across a structured program (Series A–F), revealing a reproducible continuity threshold (λ*) and a coherent band (ℂ) in parameter space. Stochastic input becomes useful signal through entropy feedback, selecting a finite spectral peak k*, while anisotropic diffusion (even in k) is cleanly separated from advection-driven drift (odd in k). Dispersion fits match theory; robustness holds under grid refinement, seeds, and parameter sweeps. This archive includes run cards, manifests, metrics, and figure sources to regenerate results end-to-end. 

Shows that the Kilgore Field Equation (KFE) acts as a stabilizing information-theoretic correction to the three-body problem (CR3BP) , extending the L4/L5 stability region beyond the classical Routh limit.  By integrating Earth–Moon–type libration orbits around L₄, we show that small positive observer-coupling parameters reduce local chaotic sensitivity, tighten invariant tori, and induce only minimal, controlled Jacobi-energy drift. All effects vanish smoothly as the coupling parameters go to zero, recovering the standard CR3BP. This work provides the first demonstration that an explicitly information-theoretic regularization can soften chaotic transport in a gravitational three-body system without breaking its structure. 

This paper investigates whether information at a black hole horizon is lost, preserved, or reorganized when modeled through the Kilgore Field Equation (KFE), an information-differentiation framework derived from Consciousness Field Theory. Using a one-dimensional horizon model, we simulate the evolution of an information field under self-differentiation, entropy feedback, observer coupling, and horizon-amplified gradients.  These results suggest that KFE horizons reorganize information rather than destroy it, providing a constructive pathway toward resolving the black hole information paradox. 

Galactic rotation curves are traditionally interpreted as evidence for non-luminous dark matter. This work presents an alternative, information-theoretic mechanism based on the Kilgore Field Equation (KFE), in which physical systems are constrained by information continuity in addition to standard gravitational dynamics.