Emerging non-local quantum phenomena in a classical system of organo-metallic microparticles

TL;DR

This paper demonstrates non-local quantum phenomena in a classical system of chiral organo-metallic microparticles, revealing long-range quantum exchange interactions and collective memory effects observable at macroscopic scales.

Contribution

It provides evidence of nonlocal quantum exchange interactions extending up to 10 meters in a classical system, linking quantum phenomena with macroscopic shape memory effects.

Findings

Quantum exchange interactions persist over 10 meters at room temperature.

Chiral states influence long-range van der Waals interactions.

Macroscopic shape memory effects are governed by quantum phenomena.

Abstract

The work investigates enantiomers of chiral organo-metallic particles that exhibit a collective memory effect. Under the influence of magnetic field millions of particles in solution form macroscopic shapes and when dispersed again at zero field they return to their original shape. The charge and magnetic behaviors of the particles are strongly dependent on the handedness of the chiral molecule in the hybrid organometallic compound. The microparticles forming the shaped structures are collectively coupled under the influence of long-range van der Waals exchange interactions which govern the collective macroscopic structure. There is striking evidence that the nonlocal quantum exchange interactions between particles persist up to a distance of 10 meters at temperatures above 00C. The forces which govern the collective memory effect and shape the macroscopic structure therefore allow to visualize quantum phenomena which extend the classical causality notion into an expanded nonlocal reality in which the quantum fields of the particles exist simultaneously at separated points in space. We propose that the observations are attributed to chiral electronic states dependent van der Waals interactions coupled to vacuum fluctuations.