Measurement of Neutrino's Magnetic Monopole Charge, Dark Energy and Cause of Quantum Mechanical Uncertainty

TL;DR

This paper reports experimental evidence suggesting neutrinos may possess magnetic monopole charge, proposes new Maxwell's equations, and links magnetic monopoles to quantum uncertainty and dark energy.

Contribution

It provides experimental detection of magnetic monopole charge in neutrons and introduces a new symmetric form of Maxwell's equations connecting monopoles to fundamental physics.

Findings

Detected non-zero magnetic monopole charge in neutrons

Proposed new symmetric Maxwell's equations including monopoles

Linked magnetic monopoles to quantum uncertainty and dark energy

Abstract

Charge conservation in the theory of elementary particle physics is one of the best-established principles in physics. As such, if there are magnetic monopoles in the universe, magnetic charge will most likely be a conserved quantity like electric charges. If neutrinos are magnetic monopoles, as physicists have reported the possibility, the Earth should show signs of having magnetic monopole charge on a macroscopic scale since neutrons must also have magnetic monopole charge if general charge conservation principle is valid. To test this hypothesis, experiments were performed to detect the collective effect of magnetic monopole charge of neutrons on the earth's equator using two balanced high strength neodymium rod magnets. We were able to identify non-zero magnetic monopole charge of the individual neutrons from the experiments. The presence of individual magnetic monopole charges in the universe prompted proposition of the new symmetric form of Maxwell's equations. Based on the theoretical investigation of these new Maxwell's equations, we concluded that magnetic monopole neutrinos are the cause of the origin of quantum mechanical uncertainty, dark energy and the medium for electromagnetic wave propagation in space.