Observation of apparent magnetic charges carried by ferromagnetic particles in water droplets

Mikhailov, V.F.

doi:10.1088/0305-4470/24/1/016

Cited by 5 publications

(3 citation statements)

References 6 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Let us first recall that direct measurements of Ehrenhaft (1930Ehrenhaft ( , 1944, Schedling (1950), Ferber (1950) lead to an estimate of the magnetic charge g = α e; Mikhaïlov (1982Mikhaïlov ( , 1985Mikhaïlov ( , 1987Mikhaïlov ( , 1991 obtained similar results, but using modern data analysis tools and from a large number of samples he gave an empirical estimate of the magnetic charge quantum g = α e/6. Both estimates are consistent with our quantization.…”

Section: Magnetic Charges Measurementsmentioning

confidence: 94%

Minkowski Space and Tachyon Velocity

Consiglio¹

2013

APR

View full text Add to dashboard Cite

A brief analysis of classical tachyons in Minkowski space shows that de Broglie wave phase velocity V = c²/v does not enable causality violations and gives an inversion of energy/momentum ratio between bradyons and tachyons. It leads to considering Vv = c² as a symmetry of Minkowski space where, for V > c, the signature of space-time is seen inverted. The inversion is shown coherent with Cramer’s transactional interpretation of quantum mechanics, but implies the physical existence of the past and the inexistence of the future.

In a recent paper we assume that the electron wave is a magnetic current at the origin of its mass; it leads to reversed coefficients with respect to the Dirac condition. Using space-time signature inversion we show that the monopole has, in linked electrons states, quantized velocities in agreement with the de Broglie wave phase velocity. The magnetic charge is relativistic and quantum in origin and comes from the Lorentz transformation of a quantum of current. We also show that gravitation is a natural consequence of the theory.

The predicted charges agree with experimental results from Ehrenhaft, Schedling, Ferber and Mikhaïlov. They also agree, in phenomenology, with recent results related to symmetry breaking in superconductors, and give plausible kinematics to the emission process in the Podkletlov and Poher experiments.

show abstract

Section: Magnetic Charges Measurementsmentioning

confidence: 94%

Minkowski Space and Tachyon Velocity

Consiglio¹

2013

APR

View full text Add to dashboard Cite

show abstract

“…Charges compatible with Dirac's were detected by Mikhaïlov (1991) when the ferromagnetic particle is within a water droplet, but in this experiment, the mass of the particles is increased 6 orders of magnitude. Our interpretation is that Dirac charge is a point of equilibrium, and then in specific low energy situations, a compound Dirac charge can emerge in the form of a current organized by the interaction of monopoles with surrounding matter, but, in our view, not an elementary particle.…”

Section: Magnetic Charge Detectionmentioning

confidence: 62%

Quantized Charges and Currents in the Electromagnetic Field

Consiglio¹

2013

APR

View full text Add to dashboard Cite

We consider the demonstration of Dirac charge quantization and interpret the main equation as the signature of a current of magnetic poles building the electron wave and mass. This naturally leads to opposite coefficients in Dirac’s equation, and to series of small quanta of magnetic charge g = a e/2n including one in exact agreement with Mikhaïlov experimental estimate g = a e/6. The resulting theoretical monopole wave is a quantized current of electricity that cancels or replaces the Dirac string. Energy is the effect of the magnetic current interacting with an electric charge, and the theory trivially agrees with the energy gap of hydrogen orbitals E = E₀/n². A second series of charges g = n a e comes out of the equations, which it is shown compatible with the electrons, muons and tauons mass built from a finite suite of magnetic poles. Once opposite coefficients are taken into account, the symmetry of magnetism and electricity discovered by Dirac matches with experimental charges and involves charges and currents.

show abstract

“…Let us explain correlation (9). In this case we have q = ne and G 2 = mg, where e and g are the elementary electric and magnetic charges accordingly; n = 1, 2, .…”

Section: Mce In Orthogonal Magnetic and Electric Fieldsmentioning

confidence: 99%