THE SPEED OF ROTATION OF PLANETS - WHAT IS THE REASON

THE SPEED OF ROTATION OF PLANETS - WHAT IS THE REASON

All planets revolve around their own axes. However, each of the planets rotates at its own velocity. Here are the values:

1. Mercury - one revolution around its axis in about 58 Earth days;

2. Venus - turnover for 243 days;

3. Earth - turnover for 24 hours;

4. Mars - turnover in 24 hours 37 minutes;

5. Jupiter - turnover for 9 hours and 55 minutes;

6. Saturn - turnover in 10 hours 40 minutes;

7. Uranium - turnover in 17 hours 14 minutes;

8. Neptune - turnover in 16 hours 03 minutes;

9. Pluto - turnover of 6.38 days.

The speed ​​of rotation of planets is entirely caused only by one thing – by the speed of the heating of their surface layers.

As mentioned earlier, the mechanism of rotation of planets is explained by the occurrence of the Field of Repulsion in the area of a planet, turned at this moment to the Sun. The emerging Field of Repulsion of a planet is resisted by the Field of Repulsion of the Sun and makes this area to move away from the Sun. At the same time the cooler regions of the same hemisphere tends to the Sun. Both of these factors, taken together, make the planet to rotate around its axis.

In each of two hemispheres of the planet there is a parallel of latitude, which is the boundary between the equatorial regions (and near equator), where there exists in the atmosphere a not already vanishing Field of Repulsion, and the Polar Regions, where there is no such field, and there is only a Field of Attraction. Namely on this boundary parallel a Field of Repulsion arises only in the region, which is currently rotated to the Sun. When this area is facing away from the sun, a Field of Repulsion gradually decreases and then disappears, in order to appear again when this area again will turn to the sun.

So, it is the speed of emergence of a non-permanent Field of Repulsion on the boundary parallel determines the speed of rotation of the planet.

And now let's find out on what factors the rate of arising of the Field of Repulsion on the boundary parallel depends. These factors determine the value of the speed of rotation of the planet.

The first factor affecting the speed of rotation of planets is the distance from a planet to the Sun. The distance is not important in itself. The value of the distance to the Sun informs us about the amount of solar particles with Fields of Repulsion reaching a planet. The shorter the distance to the Sun is, than the more solar particles with Fields of Repulsion reach a planet, the more heated the surface layers are and the faster the planet rotates. Conversely, the greater the distance is, than the less number of particles reaches the planet and the slower heating of the surface layers is.

The second factor is the degree of heating of the substance of both boundary parallels separating the regions where there is not disappearing Field of Repulsion from the areas where such Field yet does not exist. Any planet has two such boundary parallels of latitude. The substance, whose degree of heating we are interested, this is a whole thickness of substance that is located under this parallel, up to the center of a planet. Degree of heating of substances means the amount of solar particles with Fields of Repulsion accumulated by chemical elements of the substance. I.e. the more solar particles with Fields of Repulsion are accumulated by the substance of a planet in the area of these parallels, than the faster a not constant Field of Repulsion arises at a planet, and the faster a planet rotates. The greater extent of heating of the bowels of the planet, the less its Field of Attraction is. This means that elementary particles from the Sun reached the planet and accumulated by chemical elements of the surface layers (of the atmosphere) will move down more slowly towards the center of the planet. Therefore, a necessary Field of Repulsion will be formed by these particles faster.

The third factor is the atmospheric composition of planets and its thickness (if it is presented at a planet). The more sparse (the less dense) gases form the planet's atmosphere, the easier this atmosphere can start to produce a Field of Repulsion – i.e. can begin to emit Ether. The explanation is that the smaller the gas density is, the faster these elements form a Field of Repulsion during the accumulation of particles with Fields of Repulsion by chemical elements of gas. In the language of modern physics, the less dense gas is easier to heat. But denser gases are more difficult to heat. This means that for the occurrence of Field of Repulsion at elements forming these gases they must accumulate (absorb) more particles with Field of Repulsion.

As it is known, the most low density gases are included in the atmospheres of the giant planets. Such gases as helium and hydrogen are very easy to heat, and they quickly begin to emit ether – i.e. a Field of Repulsion arises at them very quickly.

Now, if we summarize these three factors and analyze their impact in relation to specific planets of the solar system, we will get something like this.

As you know, the giant planets rotate most rapidly: Jupiter – a turnover for 9 hours and 55 minutes, Saturn - 10 hours 40 minutes, Uranus - 17 hours 14 minutes, Neptune - 16 hours 03 minutes. As you can see Jupiter and Saturn are the fastest. But the distance factor is not on their side. Four planets are closer to the Sun than Jupiter, and five planets are closer than Saturn. Distance from the Sun of other giant planets is more. Nevertheless, even the most remote giant planet - Neptune - rotates faster than any of the terrestrial planets. What's the matter? The reason is a combined influence of two other factors - the degree of heating of the planet and measure of sparseness of its atmosphere.

The farther from the sun there is a planet, the more heated substance is in the area of its boundary parallels. And the giant planets, which are located from the Sun farther than terrestrial planets, are formed from the solar substance earlier and therefore longer feel the effects of solar rays.

And, of course, the atmosphere of the giant planets has a larger percentage of such rarefied gases as helium and hydrogen, and this also contributes to a higher speed of their heating and hence a higher speed of rotation.

Regarding the speed of rotation of such planets of the terrestrial group like Earth and Mars, it is less than that of the giant planets, but much more than that of Mercury and Venus. The Earth revolves around its axis in 24 hours, Mars – in 24 hours 37 minutes. Earth and Mars rotate fast enough due to the greater heating of the substance than that of Mercury and Venus, and also thanks to a sufficiently high degree of sparsity of their atmospheres

The speed ​​of rotation of Mercury is so small - one revolution in 58 Earth days - due to the fact that the substance of Mercury is heated very slightly (less than all other planets), and because Mercury has virtually no atmosphere.

Now about Venus. Its rotational speed is 1 turnover for 243 days. So, the speed of rotation of Venus would have been much more, if it rotated forward and not backwards. This means that at forward rotation Venus would rotate much faster than Mercury. Besides Venus is heated stronger than Mercury and also has a pronounced atmosphere (though dense), while Mercury's atmosphere, we can say no.

Here it should be said about the fact that the speed of rotation of Uranus would be much more if it also rotated in the forward direction, and not the reverse. At the same time Uranus rotates more slowly than the more distant Neptune.

So, slow rotation of Venus and Uranus should explain so.

And now, actually, about why Venus and Uranus rotate more slowly than they would can if their rotation would be direct and not reverse.

For this, we should remember that in the mechanism of rotation of planets once two factors play an equally important role. First, it is an emergence in the heated region of the planets a Field of Repulsion that makes this area to move away from the sun. And secondly, the tendency of areas of the planet chilled out on the night side to move closer to the Sun.

The Sun's gravity field is an ethereal stream, moving counterclockwise in the direction of the poles and the polar regions of the sun (yes, the Sun also has poles). So, that hemisphere of the planet, it is the side that is in this ethereal stream closer to its source (i.e. to the Sun absorbing the ether) will experience greater attraction from the sun's magnetic poles, as the force of attraction as it is known decreases with distance. The hemisphere of the planets with direct rotation the eastern hemisphere (moving from the night side to the day) is the closest to the source of the sun's gravity field. While at the planets with the reverse rotation – it is the western hemisphere (moving from the day side to the night).

Accordingly, the second hemisphere of the planet, which is more remote from the source of the sun's gravity fields, feels far less attraction to the Sun, as the force of attraction decreases with the distance. For planets with direct rotation the more remote hemisphere is western. But for planets with reverse rotation this is the eastern hemisphere.

It is the eastern hemisphere of the planet has a Field of Attraction. And its greatest value in comparison with other areas of the planet, since it is this area was on the night side, and most of all cool. It is the eastern hemisphere through its greatest aspirations to the Sun makes the planet rotated.

In its turn the western hemisphere is characterized by the Field of Repulsion gradually turning into the Field of Attraction (due to the gradual cooling). The western hemisphere also seeks to approach to the Sun, but to a much lesser extent.

And here please note your attention. The planets with direct rotation on the western hemisphere have the area (where the Field of Repulsion disappears and instead it the Field of Attraction appears) is turned away from the Sun to such extent and is separated from the source of its Field of Attraction that for this area the shortest path to the source of the sun's gravity fields is a movement counterclockwise (i.e. continuation of existing movement). The planet does not seek to turn back clockwise.

But the western hemisphere of the planets with reverse rotation is the closest to the source of the sun's gravity field. Consequently the region of the western hemisphere (where the Field of Repulsion due to the cooling of the planet disappears and is replaced by the Field of Attraction) feels a significant Force of Attraction to the Sun. It turns out that the eastern hemisphere of the planets with reverse rotation is located from the source of the sun's gravity field further, which reduces its aspiration to the Sun. And, moreover, and the western hemisphere seeks to the Sun. As a result, this aspiration to the Sun of the western hemisphere slows down the rotation of the planet, because it prevents the aspiration to the Sun from the side of the eastern hemisphere.