SELF

52

S.B. Karavashkin and O.N. Karavashkina

In its turn, rotation of celestial body is a necessary condition for a stellar system stabilisation. When in [11] we analysed the conditions of stellar system stabilisation, we revealed that during the protostellar cloud gravitationally heats and forms the nucleus of future star, its central part actively emits thermoelectrons which form the negatively charged cocoon around the nucleus. With it the intensive radial circulation of electrons and negatively charged ions in the exterior region arises. Gradually having been ordered, this circulation causes the nucleus and cocoon rotating in the same direction. At the same time in the nucleus there go on the processes which became the cause of thermoelectron emission. As the star evolves, its nucleus gains the structure, new thermonuclear reactions start, within the nucleus active convective exchange occurs between its centre and surface. Naturally, all these processes will regularly displace the mass centre and charge centre, making these centres, with general rotation of nucleus, to describe some closed curves. Or rather, mutual displacement of mass centre and charge centre will form some single closed curve, since the mass centre displacement as such does not form the dynamic field, only displacement of centre of charged masses does. In this connection the charge centre displacement, caused by the displacement of charged masses centre, and displacement, caused by the charge redistribution on the body surface, usually form some total centre of charge, whose radius of orbiting just will determine the characteristics of dynamic electric field. So further, speaking of the centre of charge and doing not stipulating other, we in each case will mean just the total centre of charge formed by the displacement of charged masses and redistribution of the charge inside and on the surface of celestial body.

In addition, mass displacement will form the dynamic gravitational field, which also will have the spiral structure. In case of mutual inclination of orbits of mass centre and charge centre, some stars can have two planes of spirals: one plane will be determined by electric field, and another - by gravitational field. And though the frequency of charge centre orbiting is immeasurably less than the frequency of proton's orbiting, due to the positive charge of stellar nucleus, there in its environment forms the dynamic spiral field whose structure is fully similar to that shown in Fig. 5.