Magnetivity: A Speculative Framework Linking Dark Matter and Quantum Entanglement

Abstract

This paper explores the speculative concept of magnetivity as a unifying field underlying both cosmological and quantum phenomena. Specifically, it examines the hypothesis: “In the theory of magnetivity, the same underlying field that manifests as dark matter is also the substrate enabling entanglement between particles.” By reframing dark matter as an emergent effect of this hidden field and reinterpreting entanglement as its micro-scale expression, magnetivity offers a potential bridge between astrophysical mysteries and quantum nonlocality.

1. Introduction

Modern physics faces two unresolved puzzles:

1. Cosmic-scale anomaly – Observations of galaxies and large-scale structures require the presence of dark matter, an invisible mass component not directly observable via electromagnetic interaction.

2. Quantum-scale anomaly – Quantum entanglement defies classical locality, suggesting the existence of correlations between particles across space without a recognized mediating medium.

This paper introduces magnetivity as a speculative substrate that could unify these two anomalies, suggesting that both emerge from the same hidden energetic field.

2. Defining Magnetivity

• Magnetivity is proposed as a fundamental field that permeates spacetime, distinct from but interwoven with electromagnetism and gravitation.

• At the cosmological level, magnetivity is hypothesized to manifest as what is currently labeled dark matter: a non-luminous field that shapes galactic dynamics through its hidden structural influence.

• At the quantum level, magnetivity acts as the substrate of entanglement, the nonlocal connective tissue through which correlated particles remain informationally bound.

3. Dark Matter as Macroscopic Magnetivity

• Observational data (galaxy rotation curves, lensing effects, large-scale structure) traditionally demand a particulate explanation (e.g., WIMPs, axions).

• Magnetivity reframes these anomalies not as missing particles but as emergent distortions in the underlying magnetivity field.

• Thus, galaxies are embedded in magnetivity wells — invisible yet structurally binding.

4. Entanglement as Microscopic Magnetivity

• In standard quantum mechanics, entanglement correlations arise from shared wavefunctions.

• Magnetivity suggests an alternative: that entangled particles remain connected through a shared field-thread of magnetivity.

• Rather than “instantaneous” action, entanglement is reconceived as the persistence of coherence within this field.

5. Conceptual Model

• Macro expression → Magnetivity = dark matter scaffolding galaxies.

• Micro expression → Magnetivity = entanglement substrate between quantum particles.

• Both scales reveal the same hidden field, only expressed differently depending on context.

6. Implications and Testable Hypotheses

If magnetivity exists:

• Entanglement strength should vary in measurable correlation with local dark matter density or gravitational field distortions.

• Dark matter effects may reveal field-like coherence rather than particulate distribution.

• Laboratory analogues might detect field-mediated correlations between separated systems, beyond predictions of standard quantum theory.

7. Philosophical and Scientific Context

This proposal stands outside mainstream physics. It is speculative, drawing on analogical reasoning and pattern recognition rather than empirical demonstration. Yet, alternative theories often spark new ways of testing fundamental assumptions. Magnetivity offers:

• A conceptual bridge between quantum mechanics and cosmology.

• A shift from particles to fields in explaining hidden phenomena.

• A reminder that both entanglement and dark matter may reflect the same missing substrate.

8. Conclusion

The theory of magnetivity posits a unifying field whose macro expression appears as dark matter and whose micro expression manifests as quantum entanglement. While speculative, this model offers a provocative framework for exploring one of physics’ greatest challenges: unifying the unseen forces that bind galaxies and the unseen forces that bind particles.

📄 Status: Speculative White Paper – Alternative Theoretical Model