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How many degrees is the earth's axis tilted? The tilt of the Earth's axis is a fiction. The angle of inclination of the earth's axis and its gifts

Even at school, we are taught the following picture of the world. Earth is a spherical planet moving in space around a star called the Sun. The earth rotates around its axis. This axis is inclined to the ecliptic plane at an angle of 23.44 degrees. This tilt ensures the change of seasons. The tilt of the Earth itself was supposedly formed because a certain celestial body hit our planet. Every student knows this information.

Scientists also dance from them in their scientific constructions. No one checks the correctness of such statements. But I checked it. And it turned out that everything that was instilled in us at school is sick nonsense, in which there is not a grain of truth.

So, let's start with the impact of a celestial body. Let's not argue that we must first prove that space exists. After all, this concept itself initially did not mean interstellar space at all. Cosmos was the personal name for Earth in Greek, and it denoted the order and beauty of our “planet.”

It is impossible to prove the existence of space today, because so far humanity does not even have an understanding that such a thing could exist. But we can see the impact on the Earth by a certain celestial body experimentally. The same astronauts, who were in zero gravity, more than once demonstrated experiments with a gyroscope, hitting it with a hammer. After the impact, the gyroscope axis never changed its direction.

The earth in the official version is a gyroscope. No blow can change the axis of such a rotating body. Thus, we must look for another explanation for the change in soybean slope. If, of course, such a change ever took place. Let us remember that scientists tell us that the change in the tilt of the axis supposedly took place many millions of years ago. But this is an outright lie.

Let's remember the school course in orienteering. South is in the direction of the summer solstice, north is in the direction of the winter solstice. The east is in the direction of the vernal equinox, and the west is in the direction of the autumn equinox. These directions are reflected in the calendar. And here we find the answer to the so-called tilt of the earth's axis.

There is a generally known and publicly available geographic map. It is dated 1452. That is, the time when the Julian calendar was used throughout the earth, and almost one and a half hundred years remained before the invention of the Gregorian calendar. So on this map the direction to the East corresponds to the date March 1st. This calendar is superimposed directly on the map, so no other interpretation is required. Everything is very simple.

That is, in the 15th century, the direction to the East, that is, on the day of the vernal equinox, fell exactly on March 1. And these days, the day of the vernal equinox has been shifted to the date March 22. All other dates of equinoxes and solstices are similarly shifted. It feels like the calendar has turned 22 days, and now the equinoxes and solstices occur 22 days later. That is, according to physicists, the tilt of the Earth’s axis happened in the 15th century? It was at this time that a certain cosmic body allegedly hit the Earth! But historians have not recorded this. And we understand that such an explanation for the change in the tilt of the Earth’s axis is outright nonsense.

But let's go back to 22 days. The calendar is late by this number of days in our time, and in the 18th and 19th centuries these days fell on the night from the 23rd to the 24th. We know about this not only from the astronomical tables of those centuries, but also from traditional holidays. Kupalo was celebrated from June 23 to 24, Karachun - from December 23 to 24, Komoeditsa - from March 23 to 24. That is, the real calendar shift took place not by 22 days but by 23.5 days. And this figure surprisingly coincides with the angle of inclination of the earth’s axis.

I will not talk about the precession of the Earth’s axis, since it is also a fiction. I’ll tell you right away why these 23.5 days of calendar shift appeared. During the use of the Julian calendar, the Earth was the center of the world, and the Sun revolved around it. People perceived the Sun as a mechanism for keeping time. The fact that this is so allows us to understand the same Bible, which says that God created the Moon and the Sun not for illumination, but for keeping time. Sundials were built on the movement of the Sun. Their design was very different from that of modern watches. And in the same way, the Julian calendar was different from the Gregorian calendar.

In modern watches, the dial is round, the point where the hand is attached is in the center of the dial, and the numbers themselves are evenly spaced around the circumference. This is the same model of the Gregorian calendar. In the Julian calendar, the dial was formed in a different way - like a sundial. The pointer attachment point was located on a circle, and the working area was 270 degrees. That is, not a full circle, but three quarters of a circle.

These 270 degrees were called day and were divided into 12 parts. Each was called an “hour,” that is, a part. There was an average of 22.5 degrees per hour. In the Julian calendar, night was not taken into account, since there was no star in the sky. The quarter circle was simply not used. When the Gregorian calendar replaced the Julian calendar, the new time reckoning began to use the entire circle, so the unused quarter of the time circle was simply arithmetically added to the angular value of the Julian hour.

It turned out that approximately 23 days were added to each season. Therefore, the calendar shifted to this value. None of the Earth's axis tilted anywhere. In reality, the axis of the sundial has shifted from the periphery to the center. This was perceived as axis tilt. And as a result, the calendar began to be late by 23 days.

Another mystery of the Earth has been solved...

Andrey Tyunyaev,

editor-in-chief of the newspaper "President"

> > > Tilt of the Earth

Earth's axis tilt: description of the earth's axis in relation to the ecliptic of the solar system with photos, change of seasons, north and south poles, characteristics of precession.

Previously, it was believed that our planet could be flat, zigzag or cubic in shape. But long-term studies show that we are one of the spheroids orbiting our star.

We know a lot about the orbital path, distance from the Sun, and axial tilt. Let's understand what the Earth's tilt looks like.

Earth's tilt and earth's axis

The vertical planetary axis of rotation is located at a certain angle. This results in the sun's rays being distributed unevenly throughout the year. The angle reaches 23.44°.

Effect of Earth's tilt

Seasonal differences

It is this tilt of the Earth's axis that we have to thank for the changing seasons. When the north pole is turned towards the star, summer begins on it, and winter begins on the south pole. After 6 months they change places.

In addition, the angle of the Earth's inclination affects the daily cycle. In summer, the sun rises higher and the days last longer. The most extreme situation occurs over the Arctic Circle, where there is no daylight for part of the year, as well as 6 months of darkness at the North Pole (polar night). At the South Pole the situation is the opposite, where a day can span 24 hours!

Seasons are determined by the solstices (December 21 and June 21) and equinoxes (March 20 and September 22).

Changes over time

The axial tilt remains stable for a long time. But there is such a thing as nutation - swaying with a frequency of 18.6 years. The axis goes through this process which causes it to deviate slightly.

Precession causes the dates of the seasons to change on a cyclic basis of 25,800 years. This not only causes a difference between the green manure and tropical years, but also reverses the seasons. That is, in the northern hemisphere, summer will begin in December and winter in June.

The change in the length of the day also depends on precession. This is the moment when the dates of perihelion and aphelion change. In general, you can see that axial rotation and orbital path are related to many factors. Believe me, people were once shocked to learn that the Earth was capable of moving. Even Copernicus and Galileo believed that we live on a perfect sphere.

The change in seasons that makes us feel cold right now is actually extremely important to life on Earth. Seasons are the most important mechanism for maintaining the general temperature regime on the planet. The reason for this phenomenon is the tilt of the Earth's rotation axis to the ecliptic plane. Rene Geller, a collaborator, believes that astrobiology has not yet paid enough attention to this important fact when assessing the possible habitability of exoplanets.
“Axial tilt and the changing seasons are an important consideration in considering the habitability of an exoplanet, and it has so far been almost completely ignored,” says Geller.
To fill this gap, Geller and his colleagues published two papers on the evolution of the planet's tilt axis under the influence of the gravitational field of the star and other planets. Their study showed that the tilt decreases over time, and this happens especially quickly for planets located in the habitable zones of red dwarfs, and these are the most potentially habitable planets. The tilt of the exoplanet's rotation axis under such conditions drops so quickly that life simply does not have time to arise on such a planet. Gliese 581d, one of the most famous candidates for the existence of life, also falls under this scenario.
However, there is good news. For Earth-sized planets orbiting Sun-like stars, the time it takes billions of years for the tilt to fall to dangerous levels. This is the situation facing planet Kepler-22b, the first Earth-like exoplanet in the habitable zone.
The inclination of the Earth's rotation axis to the ecliptic plane is now about 23.5 degrees, but its evolution on a geological time scale is still unknown. In general, this tilt, as well as rotation around its own axis (the change of day and night) leads to the fact that the difference between the maximum and minimum temperatures on Earth is about 111 degrees. An impressive difference, but what happens if you remove the tilt of the Earth’s axis?

When the rotation axis is tilted less than 5 degrees, the equatorial regions will always receive maximum heat. At the same time, the poles will receive almost nothing: the sun's rays will simply “slide” from the surface of the Earth without heating it, whereas now the south pole is turned towards the Sun. The result is a strong temperature gradient depending on latitude. In such conditions, everything depends on luck. A planet could lose its entire atmosphere due to its heating above the equator, causing heated air to escape into space against Earth's gravity. If this does not happen, then in the middle latitudes there may be areas suitable for life.
The planet acquires an inclination of its rotation axis during its formation under the influence of the gravitational fields of other objects. Likewise, their gravitational field can cause them to lose their tilt. Geller's group simulated this process for Gliese 581d. The simulation took into account only the planet itself and its star. Since the star's gravitational field pulls more strongly on the side that is closest to it, deforming tidal forces arise, changing the shape of the planet. The friction that arises in this case leads to damping of the angular velocity of the planet and, as a result, a decrease in its inclination. The Moon is responsible for similar processes on Earth.
“The torque generated by tidal and gravitational forces tends to position the planet so that its axis of rotation is perpendicular to the line connecting the centers of mass,” explains Geller.
The time it takes for a planet to lose tilt depends on the star. The fainter a star shines, the closer a planet must be to it to enter the habitable zone. For many stars, planets must have orbits no larger than Mercury's orbit in the solar system. But the closer the planet is to the star, the stronger gravity acts on it and, therefore, the faster it loses the tilt of its rotation axis.
For a planet with the size and mass of the Earth and located in the habitable zone of a star with a quarter of the mass of the Sun, the tilt of the rotation axis disappears in less than 100 million years. It turns out that in order to maintain the axis of rotation for a long time, the conditions must be exactly the same as in which we live. The Earth can maintain a noticeable tilt for a billion years only if the star has a mass of at least 90% solar.
“We found that Earth-like planets in the habitable zones of light stars lose tilt over a period of time markedly shorter than the evolution of life on Earth,” says Geller.
The axial tilts of super-Earths should also decrease rapidly if they orbit a red dwarf. Gliese 581d, a super-Earth, orbits a red dwarf with just 31% the mass of the Sun, and the entire system is about 9 billion years old—twice as old as the Solar System. So this planet should have lost its tilt long ago.


In addition to the loss of the angle of inclination of the rotation axis, tidal forces cause a gradual loss of angular velocity, as a result of which the planet turns one side towards the star. This is even more detrimental to life.
For stars comparable to the Sun, the habitable zone lies much further. The earth is one example of such a situation. But besides the star, there are other factors that influence the tilt. The presence of the moon and other planets leads to the emergence of new gravitational forces. In the solar system, Jupiter is the planet to fear the most, but we're lucky. The Earth was saved from the influence of this huge planet by the Moon, which compensated for its gravitational influence.
But Mars was not lucky. The influence of Jupiter can rotate the axis of rotation of this planet by 60 degrees per million years. Such sudden changes in temperature and movement of glaciers would be fatal to life.
Geller's group has not yet carried out simulations taking into account other planets and moons due to the high computational complexity of the work. However, their model allows this to be done. However, an exact calculation can wait. In any case, the current state of telescope development does not allow observing the rotation of exoplanets, so any theory regarding the tilt of the rotation axis cannot be tested.

Our planet is constantly in motion:

  • rotation around its own axis, movement around the Sun;
  • rotation with the Sun around the center of our galaxy;
  • movement relative to the center of the Local Group of galaxies and others.

Movement of the Earth around its own axis

Rotation of the Earth around its axis(Fig. 1). The earth's axis is taken to be an imaginary line around which it rotates. This axis is deviated by 23°27" from the perpendicular to the ecliptic plane. The Earth's axis intersects with the Earth's surface at two points - the poles - North and South. When viewed from the North Pole, the Earth's rotation occurs counterclockwise, or, as is commonly believed, with west to east. The planet completes a full rotation around its axis in one day.

Rice. 1. Rotation of the Earth around its axis

A day is a unit of time. There are sidereal and solar days.

Sidereal day- this is the period of time during which the Earth will turn around its axis in relation to the stars. They are equal to 23 hours 56 minutes 4 seconds.

Sunny day- this is the period of time during which the Earth turns around its axis in relation to the Sun.

The angle of rotation of our planet around its axis is the same at all latitudes. In one hour, each point on the Earth's surface moves 15° from its original position. But at the same time, the speed of movement is inversely proportional to the geographic latitude: at the equator it is 464 m/s, and at a latitude of 65° it is only 195 m/s.

The rotation of the Earth around its axis in 1851 was proved in his experiment by J. Foucault. In Paris, in the Pantheon, a pendulum was hung under the dome, and under it a circle with divisions. With each subsequent movement, the pendulum ended up on new divisions. This can only happen if the surface of the Earth under the pendulum rotates. The position of the pendulum's swing plane at the equator does not change, because the plane coincides with the meridian. The Earth's axial rotation has important geographical consequences.

When the Earth rotates, centrifugal force arises, which plays an important role in shaping the shape of the planet and reduces the force of gravity.

Another of the most important consequences of axial rotation is the formation of a rotational force - Coriolis forces. In the 19th century it was first calculated by a French scientist in the field of mechanics G. Coriolis (1792-1843). This is one of the inertia forces introduced to take into account the influence of rotation of a moving frame of reference on the relative motion of a material point. Its effect can be briefly expressed as follows: every moving body in the Northern Hemisphere is deflected to the right, and in the Southern Hemisphere - to the left. At the equator, the Coriolis force is zero (Fig. 3).

Rice. 3. Action of the Coriolis force

The action of the Coriolis force extends to many phenomena of the geographical envelope. Its deflecting effect is especially noticeable in the direction of movement of air masses. Under the influence of the deflecting force of the Earth's rotation, the winds of temperate latitudes of both hemispheres take a predominantly western direction, and in tropical latitudes - eastern. A similar manifestation of the Coriolis force is found in the direction of movement of ocean waters. The asymmetry of river valleys is also associated with this force (the right bank is usually high in the Northern Hemisphere, and the left bank in the Southern Hemisphere).

The rotation of the Earth around its axis also leads to the movement of solar illumination across the earth's surface from east to west, i.e., to the change of day and night.

The change of day and night creates a daily rhythm in living and inanimate nature. The circadian rhythm is closely related to light and temperature conditions. The daily variation of temperature, day and night breezes, etc. are well known. Circadian rhythms also occur in living nature - photosynthesis is possible only during the day, most plants open their flowers at different hours; Some animals are active during the day, others at night. Human life also flows in a circadian rhythm.

Another consequence of the Earth’s rotation around its axis is the time difference at different points on our planet.

Since 1884, zone time was adopted, that is, the entire surface of the Earth was divided into 24 time zones of 15° each. Behind standard time take the local time of the middle meridian of each zone. Time in neighboring time zones differs by one hour. The boundaries of the belts are drawn taking into account political, administrative and economic boundaries.

The zero belt is considered to be the Greenwich belt (named after the Greenwich Observatory near London), which runs on both sides of the prime meridian. The time of the prime, or prime, meridian is considered Universal time.

Meridian 180° is taken as international date line- a conventional line on the surface of the globe, on both sides of which the hours and minutes coincide, and the calendar dates differ by one day.

For a more rational use of daylight in summer, in 1930, our country introduced maternity time, one hour ahead of the time zone. To achieve this, the clock hands were moved forward one hour. In this regard, Moscow, being in the second time zone, lives according to the time of the third time zone.

Since 1981, from April to October, time has been moved forward one hour. This is the so called summer time. It is introduced to save energy. In summer, Moscow is two hours ahead of standard time.

The time of the time zone in which Moscow is located is Moscow.

Movement of the Earth around the Sun

Rotating around its axis, the Earth simultaneously moves around the Sun, going around the circle in 365 days 5 hours 48 minutes 46 seconds. This period is called astronomical year. For convenience, it is believed that there are 365 days in a year, and every four years, when 24 hours out of six hours “accumulate”, there are not 365, but 366 days in a year. This year is called leap year and one day is added to February.

The path in space along which the Earth moves around the Sun is called orbit(Fig. 4). The Earth's orbit is elliptical, so the distance from the Earth to the Sun is not constant. When the Earth is in perihelion(from Greek peri- near, near and helios- Sun) - the point of orbit closest to the Sun - on January 3, the distance is 147 million km. It is winter in the Northern Hemisphere at this time. Greatest distance from the Sun in aphelion(from Greek aro- away from and helios- Sun) - greatest distance from the Sun - July 5th. It is equal to 152 million km. It's summer in the Northern Hemisphere at this time.

Rice. 4. The movement of the Earth around the Sun

The annual movement of the Earth around the Sun is observed by the continuous change in the position of the Sun in the sky - the midday altitude of the Sun and the position of its sunrise and sunset change, the duration of the light and dark parts of the day changes.

When moving in orbit, the direction of the earth's axis does not change; it is always directed towards the North Star.

As a result of changes in the distance from the Earth to the Sun, as well as due to the inclination of the Earth's axis to the plane of its movement around the Sun, an uneven distribution of solar radiation is observed on Earth throughout the year. This is how the change of seasons occurs, which is characteristic of all planets whose axis of rotation is tilted to the plane of its orbit. (ecliptic) different from 90°. The orbital speed of the planet in the Northern Hemisphere is higher in winter and lower in summer. Therefore, the winter half-year lasts 179 days, and the summer half-year - 186 days.

As a result of the Earth's movement around the Sun and the tilt of the Earth's axis to the plane of its orbit by 66.5°, our planet experiences not only a change of seasons, but also a change in the length of day and night.

The rotation of the Earth around the Sun and the change of seasons on Earth are shown in Fig. 81 (equinoxes and solstices in accordance with the seasons in the Northern Hemisphere).

Only twice a year - on the days of the equinox, the length of day and night throughout the Earth is almost the same.

Equinox- the moment in time at which the center of the Sun, during its apparent annual movement along the ecliptic, crosses the celestial equator. There are spring and autumn equinoxes.

The tilt of the Earth's rotation axis around the Sun on the days of the equinoxes March 20-21 and September 22-23 turns out to be neutral with respect to the Sun, and the parts of the planet facing it are evenly illuminated from pole to pole (Fig. 5). The sun's rays fall vertically at the equator.

The longest day and shortest night occur on the summer solstice.

Rice. 5. Illumination of the Earth by the Sun on the days of the equinox

Solstice- the moment the center of the Sun passes the points of the ecliptic most distant from the equator (solstice points). There are summer and winter solstices.

On the day of the summer solstice, June 21-22, the Earth occupies a position in which the northern end of its axis is tilted towards the Sun. And the rays fall vertically not on the equator, but on the northern tropic, the latitude of which is 23°27". Not only the polar regions are illuminated around the clock, but also the space beyond them up to a latitude of 66°33" (the Arctic Circle). In the Southern Hemisphere at this time, only that part of it that lies between the equator and the southern Arctic Circle (66°33") is illuminated. Beyond it, the earth's surface is not illuminated on this day.

On the day of the winter solstice, December 21-22, everything happens the other way around (Fig. 6). The sun's rays are already falling vertically on the southern tropics. The areas that are illuminated in the Southern Hemisphere are not only between the equator and the tropics, but also around the South Pole. This situation continues until the spring equinox.

Rice. 6. Illumination of the Earth on the winter solstice

On two parallels of the Earth on solstice days, the Sun at noon is directly above the observer’s head, i.e. at the zenith. Such parallels are called the tropics. In the Northern Tropic (23° N) the Sun is at its zenith on June 22, in the Southern Tropic (23° S) - on December 22.

At the equator, day is always equal to night. The angle of incidence of the sun's rays on the earth's surface and the length of the day there change little, so the change of seasons is not pronounced.

Arctic Circles remarkable in that they are the boundaries of areas where there are polar days and nights.

Polar day- the period when the Sun does not fall below the horizon. The farther the pole is from the Arctic Circle, the longer the polar day. At the latitude of the Arctic Circle (66.5°) it lasts only one day, and at the pole - 189 days. In the Northern Hemisphere, at the latitude of the Arctic Circle, the polar day is observed on June 22, the day of the summer solstice, and in the Southern Hemisphere, at the latitude of the Southern Arctic Circle, on December 22.

polar night lasts from one day at the latitude of the Arctic Circle to 176 days at the poles. During the polar night, the Sun does not appear above the horizon. In the Northern Hemisphere at the latitude of the Arctic Circle, this phenomenon is observed on December 22.

It is impossible not to note such a wonderful natural phenomenon as white nights. White Nights- these are bright nights at the beginning of summer, when the evening dawn converges with the morning and twilight lasts all night. They are observed in both hemispheres at latitudes exceeding 60°, when the center of the Sun at midnight falls below the horizon by no more than 7°. In St. Petersburg (about 60° N) white nights last from June 11 to July 2, in Arkhangelsk (64° N) - from May 13 to July 30.

The seasonal rhythm in connection with the annual movement primarily affects the illumination of the earth's surface. Depending on the change in the height of the Sun above the horizon on Earth, there are five lighting zones. The hot zone lies between the Northern and Southern tropics (Tropic of Cancer and Tropic of Capricorn), occupies 40% of the earth's surface and is distinguished by the largest amount of heat coming from the Sun. Between the tropics and the Arctic Circles in the Southern and Northern Hemispheres there are moderate light zones. The seasons of the year are already pronounced here: the further from the tropics, the shorter and cooler the summer, the longer and colder the winter. The polar zones in the Northern and Southern Hemispheres are limited by the Arctic Circles. Here the height of the Sun above the horizon is low throughout the year, so the amount of solar heat is minimal. The polar zones are characterized by polar days and nights.

Depending on the annual movement of the Earth around the Sun, not only the change of seasons and the associated unevenness of illumination of the earth’s surface across latitudes, but also a significant part of the processes in the geographical envelope: seasonal changes in weather, the regime of rivers and lakes, rhythms in the life of plants and animals, types and timing of agricultural work.

Calendar.Calendar- a system for calculating long periods of time. This system is based on periodic natural phenomena associated with the movement of celestial bodies. The calendar uses astronomical phenomena - the change of seasons, day and night, and changes in lunar phases. The first calendar was Egyptian, created in the 4th century. BC e. On January 1, 45, Julius Caesar introduced the Julian calendar, which is still used by the Russian Orthodox Church. Due to the fact that the length of the Julian year is 11 minutes 14 seconds longer than the astronomical one, by the 16th century. an “error” of 10 days accumulated - the day of the vernal equinox did not occur on March 21, but on March 11. This error was corrected in 1582 by decree of Pope Gregory XIII. The counting of days was moved forward 10 days, and the day after October 4 was prescribed to be considered Friday, but not October 5, but October 15. The vernal equinox was again returned to March 21, and the calendar began to be called the Gregorian calendar. It was introduced in Russia in 1918. However, it also has a number of disadvantages: unequal length of months (28, 29, 30, 31 days), inequality of quarters (90, 91, 92 days), inconsistency of the numbers of months by day of the week.

The topic of shifting the Earth's rotation axis has been discussed on the Internet for several years now - since the time when some people who had been living in the same place for a long time began to note that the Sun rises and sets in a different place from where it always was during the corresponding period. When people try to discuss this phenomenon, crowds of trolls and ordinary brainless people howling at them always appear, starting to talk about refraction-diffraction and so on. However, let's look at the facts.

Alaska is home to a tribe of local aboriginals who call themselves Inuk or Inuit. The words “raw meat eater” sound like “Eskimo” in their language, which gave another name to the tribe. Living in the far north and not having new-fangled satellite devices, the Inuit have been carefully observing the Sun and stars for centuries, and have their own unshakable calendars of all seasonal phenomena. But since the beginning of the 2000s, these calendars have been greatly shaken, which the elders even tried to inform NASA about.

Effect of Earth's tilt and motion around the Sun

According to their observations, the Sun rises and sets in the WRONG WHERE and WRONG WHEN. The Inuit, who have some knowledge of conventional astronomy, suggested that since the Earth is round and rotates, then the axis of rotation must have changed if the Sun does not rise above the hill over which it has risen for centuries on that day. Enlightened adepts from NASA laughed at the ignorant Indian guys and hushed up the topic. However.

People who lived in one place for a long time, decades, began to notice that the Sun now sets and rises in a completely different place from where it rose and set 20 or 40 years ago. A natural question arises - why?

Let's turn to scientific information regarding the angle of inclination of the Earth's rotation axis:

The angle of inclination of the Earth's axis relative to the ecliptic plane is 23.5 degrees. This caused the change of seasons on Earth, as a result of rotation around the Sun.

Imagine that the Sun is in the center of a rotating gramophone record. All planets, including the Earth, revolve around the Sun, like the tracks of a gramophone record. Now imagine that each planet is a top, the top and bottom points of which coincide with the angle of rotation of the Earth around the Sun. By measuring the angle of inclination between the poles and the orbit in which the Earth moves around the Sun, you will get exactly that 23.5 degrees.

Graphic representation of the Earth's tilt

At one point in the Earth's orbit, the Earth's North Pole faces the Sun. At this time, summer begins in the northern hemisphere. 6 months later, when the Earth is on the opposite side of its orbit, the North Pole points away from the Sun and winter sets in, while summer sets in in the southern hemisphere.

With a periodicity of 41 thousand years, the angle of inclination of the earth's axis changes from 22.1 to 24.5 degrees. The direction of the earth's axis also changes with a period of 26 thousand years. During this cycle, the poles change places every 13 thousand years.

All planets of the solar system have a certain angle of inclination of their axis. Mars has an inclination angle very similar to Earth's and is 25.2 degrees, while Uranus has an inclination angle of 97.8 degrees.

Great, science describes everything to us in detail, but these data have not changed for decades, and the tilt of the Earth’s axis changes. The sun rises and sets in a completely different place, and in addition, global climate change may not be associated with the notorious human impact on nature, but with a change in the tilt of the Earth, as a result of which the climate has changed, moreover, all natural anomalies point precisely to this factor.

Why is this happening? The answer suggests itself - some huge cosmic body has entered the Solar System and is exerting a powerful gravitational influence on our planet, it is so strong that it has already changed the Earth’s axis of rotation.

Scientists cannot help but know, they cannot help but record such changes in the tilt of the earth’s axis, but for some reason they are in no hurry to change the information, correct the data on the angle of inclination, and are certainly not in a hurry to explain why all this is happening.

The changes are noticed by many people who write about it, but science is silent. Popular unofficial radio host in the US, Hal Turner, recently raised this topic on his show and described his observations in detail.

Here's what he said:

"The sun is setting much further north than before. I live in North Bergen, NJ 07047. My house is located on a western slope, 212 feet above sea level. I moved here in 1991, I live on the third floor, with a balcony facing west For many years I enjoyed beautiful sunsets from this balcony, and at the beginning of the summer of 2017, I unexpectedly noticed that the Sun was setting in a completely different place than before.

It used to set in the west, but now it sets in the northwest. Moreover, it has shifted so much that if earlier I watched the sunset looking straight ahead, now, in order to see the sunset, I am forced to turn my head to the right.

I am not a scientist or an academician, but I have lived here for 26 years and I see that the Sun sets in a completely different place from where it used to be. The only reasonable explanation for this fact is that the Earth has changed the angle of its axis. Why does NASA pray, why don’t all the scientists in the world notice or don’t want to notice this?”

Influence of Planet X (Nibiru)?

According to ancient Sumerian texts and recent research by modern scientists, the appearance of Planet X in the Solar System will change the tilt of the Earth's axis, which will cause global climate change, and as this planet approaches the Earth, this will lead to large-scale natural disasters - tsunamis and other natural phenomena that will most likely destroy life on our planet.

Judging by the fact that billionaires, governments and other rulers of the world are preparing reliable shelters for themselves, creating “arks” for storing seeds and the cultural heritage of human civilization, they know about the approaching global catastrophe

Perhaps this is why the space programs of NASA, Elon Musk (Space X) and Jeff Bezos (Blue Origin) began to actively develop, the goal of which is to resettle a select few to other planets and create colonies there.

Nibiru, also known as Planet X, is considered a planet whose orbit at perihelion crosses the Solar System between Mars and Jupiter once every 3600-4000 years. The Sumerians left a description of this planet which says that highly developed intelligent beings live on it - the Anunnaki.

Not so long ago, just a few years ago, scientists called information about Planet X a myth and pseudoscience, and then these same people who laughed at Nibiru themselves announced the discovery of Planet X. Maybe it’s time to openly tell people about the real causes of global climate change and tell us about planet X too. Maybe the time has already come?