What question did this study set out to answer?

This framework aims to explain dark matter behavior using quantum mechanical principles.

March 30, 2026Open Access

The Quantum-Observer Effect in Dark Matter Dynamics: A Hybrid Wave-Particle Duality Model

Key Points

This framework aims to explain dark matter behavior using quantum mechanical principles.
Proposed a conceptual model based on Quantum Mechanics
Hypothesized density-dependent wave-particle duality for dark matter
Explored behaviors in low-density and high-energy environments
Identified coherent wave state of dark matter in low-density galactic halos
Described gravitational decoherence and particle-like behavior in high-energy cosmic environments
Proposed cosmic observer effect for separating dark mass from baryonic gas without complex terms.

Abstract

This conceptual paper proposes a novel framework for Dark Matter (DM) behavior based on the principles of Quantum Mechanics. We hypothesize that DM exhibits a "Density-Dependent Wave-Particle Duality." In low-density environments, such as galactic halos, DM exists in a coherent wave state, behaving as a gravitational field. However, in high-energy environments or violent cosmic collisions (e.g., the Bullet Cluster), the system undergoes "Gravitational Decoherence," causing the wave-function to collapse into a particle-like state. This "Cosmic Observer Effect" provides a potential explanation for the physical separation of dark mass from baryonic gas without requiring complex self-interaction terms.

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