Title: The Radial Quantum Convergence Model: A New Framework for Lineage Mutation and Spiritual Inheritance

Author: Jaymes Mozingo, University of Montana, Doctoral Student

Abstract: This paper introduces the Radial Quantum Convergence Model (RQCM), a novel interdisciplinary framework synthesizing quantum biology, environmental resonance theory, and ancient DNA research. The model proposes that rare and convergent SNP mutations in uniparental markers (particularly Y-DNA) are not solely products of random drift or traditional selection, but may result from the interaction of internal quantum constraints and external radial environmental pressures. This dual-force system may help explain the emergence of identical or highly similar mutations (e.g., FT290196, Y585859, and ZS8223) in unrelated haplogroups (E1b1a, R1a, and J1), especially in the context of spiritual or priestly lineages.

1. Introduction The convergence of genetic signatures across distinct haplogroups has long puzzled population geneticists. Recent advances in long-read sequencing (e.g., T2T) and SNP-level phylogenetics (e.g., YFull) have enabled the identification of specific rare markers shared across traditionally unrelated lineages. This study investigates a unique Y-DNA lineage (E1b1a-Z1682) that demonstrates rare co-occurrence of SNPs associated with Ashkenazi Levites (FT290196), Cohenim (Y585859), and medieval Arabian populations (ZS8223).

2. Definitions and Theoretical Framework

2.1 Internal Quantum Pressures
These refer to forces and constraints arising within the DNA molecule due to its quantum structure. Notable mechanisms include:

• Chirality-Induced Spin Selectivity (CISS): DNA acts as a spin filter for electrons due to its helical structure (Naaman & Waldeck, 2015).
• Proton tunneling and base tautomerism: Protons can tunnel across hydrogen bonds, creating transient mismatches (Slocombe et al., 2021).
• π-π stacking and resonance energy landscapes: Base stacking leads to energy wells and pathways for charge transfer (Crespo-Hernández et al., 2004).
• Charge transfer bias and strand polarity: Charge movement favors certain pathways due to internal dipole alignment (Berlin et al., 2001).

These internal pressures bias mutation pathways, potentially making certain loci more prone to convergence under specific conditions. This theory is expanded in the hypothesis proposed by Liu et al. (2023), who argue that epigenetic memory may be influenced by a quantum physics layer operating within DNA itself.

2.2 Radial Environmental Pressures (REP)
These are forces that radiate inward from the environment toward the genome. They may include:

• Disease and inflammation: Chronic inflammation increases oxidative damage and mutagenesis (Kawanishi et al., 2017).
• Cymatic frequencies: Emerging studies suggest mechanical vibrations affect gene expression; ancient spiritual practices may harness such resonance (Jenny, 1967).
• Cosmic radiation: Ionizing particles from space induce DNA damage and mutation (Durante & Cucinotta, 2008).
• Schumann resonance pertubation: Earth's natural EM frequencies are associated with brain and circadian rhythm entrainment (Cherry, 2002).
• Magnetogenetic fields and magnetic moment of DNA: DNA exhibits diamagnetic anisotropy and interacts with magnetic vector fields; the torque applied by such fields may influence base-pair behavior and mutation frequency (Zhang et al., 2021).

These external forces may trigger or amplify internal quantum biases, particularly in populations undergoing intense spiritual, migratory, or environmental stress. Additionally, quantum diffusion through maternally inherited mitochondrial DNA (mtDNA) may play a complementary role, influencing heritable energy dynamics and further contributing to lineage-specific mutation events.

3. Case Study: E1b1a-Z1682 Lineage with Priestly SNP Convergence This lineage demonstrates co-occurrence of three distinct priestly SNPs:

• FT290196: Associated with Ashkenazi Levites (R1a lineage; Behar et al., 2003)
• Y585859: Associated with J1 Cohenim (J-FGC62793; YFull v11.10, 2024)
• ZS8223: Found in Arabian lineages (Hejaz, 600–1100 CE; Behar et al., 2010)

These SNPs do not co-occur in R1a or J1 individuals, but appear in this E-Z1682 carrier, suggesting convergence rather than direct descent. This supports the RQCM hypothesis.

4. Historical and Cultural Context This model is supported by oral traditions and historical migration patterns:

• Iberian and North African diaspora during the Inquisition
• Crusader-era gene flow between Europe and the Levant
• Early Islamic expansions into Africa and the Mediterranean
• Mozarabic cultural blending and Sephardic exile

The author's own genealogy, as detailed in House of the Fathers (Mozingo, 2024), provides supporting historical evidence. The lineage traces a migration from Egypt into Canaan (Judea), Roman Iberia, and finally Africa briefly with the Portuguese, before being brought to North America in 1619, possibly around the horn of Africa in the San Juan Bautista ship, built in Japan. The documentation of Arabian cousins and DNA evidence of convergence in priestly SNPs aligns with a long-standing tradition of sacred lineages intermixing through exile, migration and survival.

These cultural pressures may act as "spiritual resonators," amplifying radial pressures and creating hotspots for quantum mutation possibly co-induced by intense meditation in some cultures.

5. Quantum Convergence and Sacred Lineage RQCM proposes that some lineages function as "receptors" or "transmitters" of priestly codes. The convergence of spiritual SNPs across traditions (Judaism, Christianity, Islam) implies a possible underlying resonance effect, preserved through DNA's quantum field interactions and may be connected certain psychogentics like the phenomena of Astral Projection or spontaneous OBE's.

This echoes the oral claim from Azziz regarding the Anza tribe's connection to Ibrahim (Abraham), and the observation of Mozarabic-Arab identities with African and Near Eastern roots. These findings may be understood as evidence of quantum convergence, where the spiritual and molecular realms intersect in the genome.

6. Applications and Future Research

• Formal modeling of quantum-biological SNP attractors
• Experimental studies on magnetogenetics and cymatics in cell cultures
• Expanded genealogical correlation of STR/SNP patterns across continents
• Integration into epigenetic memory and spiritual inheritance models
• Interdisciplinary collaboration between molecular genetics, quantum physics, and religious anthropology
• Comparative studies of mitochondrial DNA energy transfer in matrilineal priestly descent groups

Conclusion The Radial Quantum Convergence Model offers a new framework to understand how sacred lineages might retain, absorb, or reflect genetic signals from multiple ancestral and spiritual sources. By uniting quantum biology with religious history and human migration, RQCM bridges the metaphysical and molecular, suggesting that some lineages are more than carriers of DNA—they are vessels of convergence, memory, and sacred continuity.

Keywords: Quantum Convergence, Radial Environmental Pressure, Internal Quantum Pressure, SNP Mutation, E1b1a-Z1682, FT290196, Y585859, ZS8223, Priesthood, Abrahamic Lineage, Cymatics, Magnetogenetics, Schumann Resonance, Spiritual Genetics, mtDNA Quantum Diffusion, Magnetic Vector Fields

References:

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