SELF

72

S.B. Karavashkin and O.N. Karavashkina

Several experiments studying dynamic magnetic field

Sergey B. Karavashkin and Olga N. Karavashkina

Special Laboratory for Fundamental Elaboration SELF

187 apt., 38 bldg., Prospect Gagarina, 38, Kharkov 61140, Ukraine

Phone: +38 (057) 7370624; e-mail: selftrans@yandex.ru , selflab@mail.ru

Abstract

We substantiate three sets of experiments studying EM induction, describe and present their results. These experiments corroborate that the lines of force of dynamic magnetic field are open, as well as that the phenomenology of process of mutual induction is true if based on the direct interaction of parallel sections of primary and secondary loops. Additional theoretical calculations on the basis of this phenomenology well coincide with the experimental results.

Keywords: electromagnetic theory, dynamical magnetic field, dynamical electric field, electromagnetic induction, induction in a single conductor.

Classnames by PASC 2001: 03.50.-z; 03.50.De; 41.20.Gz; 85.30.Tv; 85.70.-w; 85.70.Ay; 85.80.Jm.

In the sections 4- 6 of [1] we have theoretically proved that the structure of electric and magnetic dynamical fields essentially differs from the structure of related stationary fields, and that in these fields other conservation laws are true. First of all, in dynamical fields, divergence of longitudinal vector and curl of transverse vector of field become time-dependent variables. With it, when in corresponding conservation laws the non-zero right-hand part appears, it does not mean the origin of magnetic monopoles in space where the dynamic field propagates. Dynamic field itself as a non-stationary process in space, "remains" the dynamic memory of conditions of its formation, and this space-non-damping "memory" propagates with the field, creating the effect of virtual electric and magnetic charges.

Furthermore, in the above paper [1] we have proved that both electric dynamic field and magnetic dynamic field are not closed as it is now conventionally thought. They are not closed because the time-dependent lag function of the field forms in space differential non-stationary strengths of the field. Just these differential strengths characterise the dynamic field, determine its structure and interaction with charges that are in these fields. But these differential strengths of the field, by force of their origin and progressive process of wave propagation in space, are potential, due to which the field itself becomes open. This last treatment of processes in dynamic fields is quite unusual in the view of conventional concepts and requires, naturally, to be experimentally corroborated.

In this paper we will describe several sets of experiments clearing the structure of dynamic magnetic field. We would like to notice, not occasionally we directed our experimental check to study just magnetic field. For electric field whose potential pattern in stationary state was long ago and multiply checked, the claim of potential dynamic field proved in [1] can be if not accepted then at least mathematically understood. But open lines of force of magnetic field in dynamic state will be admitted as a complete nonsense, as they automatically are associated with mythic magnetic monopoles. So, to understand the very possibility of open lines of force for magnetic field without any magnetic monopoles but due to specific dynamic structure of dipole, we drew our attention namely to the experimental study of the structure of dynamic magnetic field.