Helix Light Vortex Theory (HLV)

Abstract

This paper presents a concrete experimental program designed to test the core predictions of the Helix-Light-Vortex (HLV) theory. The HLV framework postulates that fundamental reality is shaped by a "Spiral Time" parameter (Ψ(t)) and a universal "Information Field" (Φ(x,t)), which should produce observable physical signatures. This proposal outlines three distinct, state-of-the-art experiments to bridge the gap between the theory's foundational concepts and measurable physics. First, we propose a search for "biogravitational" effects. This experiment will use high-precision quantum gravimeters, such as atom interferometers, and NV-center-based spin compasses to detect predicted gravitational anomalies and atomic spin shifts generated by coherent biological systems. A positive result would be the detection of synchronized signals across these different sensors. Second, we suggest an analysis of existing Cosmic Microwave Background (CMB) data from the Planck and WMAP missions, as well as future data from CMB-S4. The HLV theory predicts that Spiral Time should induce specific modulations in the large-scale patterns (low-ℓ multipoles) of the CMB spectrum. We will use harmonic decomposition and matched filtering techniques to search for these periodic signatures. Third, we outline a direct search for new "Axion-Like Quasiparticles" (ALQs). The theory predicts these scalar excitations to have a mass of approximately 10⁻⁵ eV. This search will utilize a standard microwave cavity haloscope, similar to existing dark matter experiments like ADMX, tuned to the corresponding frequency of around 2.4 GHz to detect their potential conversion into photons.