chapter2

The same pattern we see on our Sun: its field is maximal in the area of latitude (30-35)^{^o}, spots and ejections are observed also in this belt. In Fig. 2.33, a (positive) and b (negative), we see the typical pattern of spots-sinks distribution. The image 2.33c is convenient to compare with 2.32: electric field of the Sun affects the radiation so that only in polar regions its rays raise radially, but already from temperate latitudes they abruptly deflect towards the equator, and at temperate and equatorial latitudes mainly positively charged particles are radiated, and in polar - negatively charged. This is connected with the electron cocoon slowly flowing towards the equatorial plane in an adult star. Formed in this way heterogeneity of potential distribution causes also the heterogeneous distribution of beams - in the equatorial plane their density is maximal. We would notice, we are speaking here about the natural field of Sun which we do not feel and it is practically hard to measure it, as we are inside it (near the equatorial plane).

Fig. 2.33. Sun spots in positive (a) and negative (b). It is seen how the gas emanates from spots, which are more drawn to the equatorial plane. In the image (c) there is shown the general appearance of the crown of quiet Sun: beams are radial only in polar regions, but already in temperate latitudes they are considerably deflected to the equator. Both images have been copied from Total Solar Eclipse Composite by Andreas Gada and Jerry Lodriguss;

http://www.jupiterscientific.org/virtualastronomer/

Not out of interest is to notice that dense gas disk of adult galaxy behaves in the intergalactic space like Rayleigh disk - thin disk hanged on a thin thread within the gas flow. Such disk slews around across the flow, and by the angle of its inclination we can judge of the magnitude of sound (flow); Rayleigh disk is sensitive both to permanent and alternating flow [20]. This effect is explained by the non-zero divergence of vector of dynamical flow which we proved in [21]. Thus, by the disk orientation we can judge about the direction of intergalactic waves in the given region of intergalactic space either about the direction of the very galactic motion. With superimposed motions, the galactic plane can be inclined to the direction of motion and to the propagation direction of infra-low-frequent intergalactic waves. With the inclined plane of galactic disk, the nucleus shift from geometric centre will additionally affect its shape, whereupon the disk will have an eccentricity. We considered one of such galaxies in [14] and show it again (Fig. 2.34). The nucleus of this galaxy is strongly shifted relatively to its geometric centre. Together with the arm closed into a ring, which was shown in [14] to be the sign of perfectly balanced system, this tells of the intensity of outer affection on this galaxy - either of its rapid motion. By the value of eccentricity we can judge of the degree of inclination of galactic disk to the direction of motion. And the presence of inclination angle allows to judge of the intensity of infra-low frequency intergalactic waves in the region of galaxy location.

We can additionally mark, the nucleus united by common electron cocoon of the system makes it highly stable, autonomous and conservative. Being on the whole neutral, all hot celestial bodies underwent the charge separation become outwardly electro-negative and already at large distance from each other mutually repel, due to which their accidence becomes hardly probable. It is important to take into account this physical aspect for the supporters of all versions of accidental theories, in that number galaxy cannibalism theory, and in our consideration - for the supporters of theories in which our planet system arose of splinters from two stars collision. To collide, two objects would have to surmount the electron barriers of each other, and this energy expenditure can be compared with the total energy of both colliding objects. Consequently, though we cannot exclude collisions in the universe, they have to be quite seldom and to have extraordinary cause. In more attentive consideration, if not all but most objects to which collisions are attributed today have simpler and more natural explanation; many examples to it we gave in [14].

Thus, in this item we made sure that the charge separation of celestial bodies and structure of their dynamic electric fields (that never before was taken into account) determine their mechanical structure - regular evolution from globular cluster to a plane spiral shape. In its turn, the arms evolution in galaxies controls the most important process in their further evolution - secondary star formation that occurs already not in the nucleus but in spiral arms. Before, in the item 2.3, we seemingly considered this process on the whole; but if we return to it, noting these new aspects, we will now see much richer pattern and will be able to explain many new important details. So let us consider some more aspects of secondary star formation.

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O.N. Karavashkina and S.B. Karavashkin