Is it true that Venus rotates counterclockwise? and got the best answer

Answer from Ulenspiegel[guru]
Yes it's true. And Uranus generally lies "on its side."

Answer from Glukhov Ivan[newbie]
Venus rotates in the opposite direction to its orbit. That is, the sun rises in the west and sets in the east.

Answer from Ivan Vasilievich changes profession[guru]
She spins venereal, of course!

Answer from Dmitry Nizyaev[guru]
Depending on which pole you're watching from... But no matter how it spins, it's not at all surprising. And why shouldn't she, in fact, rotate at least like that, at least that way? Uranus is really amazing. It rotates completely out of the plane of its orbit, and this is a very unstable position. Strictly speaking, in the process of its formation, the planet has a chance to acquire the resulting rotation in absolutely any plane and in any direction. But if the plane of rotation of the planet does not coincide with the plane of its orbit, then tidal forces cause precession - about the same behavior as a spinning top, whose axis is not vertical. Friction forces arise along the Coriolis arcs, and these forces gradually, turn by turn, change the direction of the axis of rotation. And the closer the plane of rotation is to the plane of the orbit, the less the Corisolis forces interfere in the process - which sooner or later leads to the balancing of this plane. Therefore, most planets rotate exactly or almost exactly in the plane of their orbit.
And Uranus - rotates across! And from this one can draw one of two conclusions: either Uranus is much younger than the rest of the planets in the system, or the plane of its rotation accidentally turned out to be so close to the perpendicular to the orbit that the Coriolis forces balance each other. Figuratively speaking, the planet was in such perfect balance that it still cannot decide which side it should fall on. A rare case, it turns out!

Answer from Nikolai Gorelov[guru]
Look at the sky. The sun scratches it clockwise, which means our Earth is against the clock. Then, Venus spins clockwise, that is, not like people do.

Answer from 3 answers[guru]

Hey! Here is a selection of topics with answers to your question: Is it true that venus spins counterclockwise???

Venus is the brightest object in the sky. Although ancient people knew about Venus, some cultures believed that she was two separate celestial objects - the evening star and the morning star. The Greek astronomer was the first to realize that the evening and morning stars are actually one object. Many cultures have attributed to the planet a corresponding goddess of love and beauty. Venus is the Roman name for this goddess. The Babylonians called the planet Ishtar, while the Greeks called it Aphrodite.

The average distance from Venus to the Sun is 108.21 million kilometers. This is an average distance, since Venus moves in an elliptical orbit around the Sun. At its closest point in its orbit, called perihelion, Venus is only 107.48 million kilometers from the Sun. And then at the farthest point of its orbit, Venus is 108.94 million kilometers from the Sun.

Venus takes 224.7 days to complete one orbit around the sun. But it also takes 243.02 days to turn around on its axis. In other words, a day on Venus is actually longer than a year on Venus. It is also strange that Venus rotates in the opposite direction compared to. Seen above the north pole, Venus is seen turning clockwise. If you could stand on the surface of Venus, you would see the Sun rise in the west as it slowly moves across the sky and set in the east, unlike the Earth.

Scientists believe that Venus is a twin because of its similarity. For example, the radius of Venus is 6.052 km; 95% of the Earth's radius. The mass of Venus is 81.5% of the mass of the Earth, and the density is 5.24 g/cm 3 , while the density of the Earth is 5.51 g/cm 3 . If you were standing on the surface of Venus, you would experience 90% of the gravity you feel on Earth.

A day on Venus lasts 243 days; which is unusual considering the fact that a year on Venus is only 224.7 days long. In other words, a day on Venus is longer than its year. Moreover, Venus is the only planet in the solar system that rotates clockwise around its axis. All other planets rotate counterclockwise.

Radar imaging of the surface of Venus has shown it to have impact craters all over the planet and evidence of widespread volcanism. smaller and almost always low shield volcanoes. Some big event was thought to have reshaped the surface of Venus 300-500 million years ago, erasing older impact craters and volcanoes. This event also turned off the planet's plate tectonics, trapping heat inside the planet. Without heat escaping, convection in Venus's core also stopped and the planet lost its magnetic field. The interior of Venus is similar to the Earth. The planet has a core of metal, surrounded by a mantle of stone, and a thin crust. But unlike Earth, Venus has no plate tectonics and no carbon cycle that moves carbon out of the atmosphere and stores it inside the planet. This is one of the problems that may have led to Venus's runaway greenhouse effect.

While Venus has many similarities to Earth, it also has many differences. Perhaps the biggest difference is in its atmosphere. The atmospheric pressure on the surface of Venus is 92 times greater than at sea level. In fact, you would have to dive to a depth of 1 km below the surface of the ocean to experience the same pressure. This atmosphere is composed almost entirely of carbon dioxide, with dense clouds of sulfur dioxide. Due to the atmosphere of carbon dioxide, Venus experiences the strongest in the solar system. The temperature on the surface of Venus is 460°C, no matter where you are on the planet. It's hot enough to melt lead, and it destroyed the spacecraft in a matter of hours.

At one time, scientists and science fiction writers believed that the surface of Venus was tropical in nature. Some believe that faith was the only reason the Soviet Union launched a series of surface probes to the planet. After seven missions were destroyed under pressure before they could reach the surface, Venera 8 landed and disappointed millions. Several other probes were able to land in the following years. The last one to land was the Venus Express. He arrived in April 2006 and studied the planet's surface and atmosphere until he could no longer work.

Because of its dense clouds, Venus could not be observed from Earth. Early observations showed that the planet went through phases just like the Moon, demonstrating that it orbits the Sun inside the Earth's orbit. But until the first spacecraft observations were made, astronomers did not fully understand what was underneath the dense clouds. Radar photos from NASA's Magellan spacecraft imaged the entire planet, revealing a hellish world covered in rocks and ancient lava flows. Several Russian spacecraft landed on the surface of the planet, staying there for only a few hours and sent back photographs from the planet's surface.

Venus is often referred to as the Morning Star because it orbits closer to the Sun than our planet. This causes Venus to appear in the western sky after sunset and before sunrise in the eastern sky. In addition, only the Sun and Moon are brighter than Venus in our night sky. Because of all this, Venus is hard to ignore, even with the naked eye.

Venus has no moons or rings.

About Venus(Items without links are under development)

• Interesting facts about V.
• The history of the planet
• atmosphere B.
• How far is W. from the Sun
• Distance from Earth to V.
• Planet V. for children
• What is the gravity on V.
• How to find V. in the sky
• What does V. consist of?
• Does V. have moons?
• How did V. get her name?
• How long is a day in V.?
• diameter B.
• Retrograde rotation B.
• surface B.
• Symbol V.
• temperature B.
• Does V. have rings?
• How long is a year in V.?
• Does V. have volcanoes?
• Video V.
• Color V.
• Orbit V.
• How many moons does V. have?
• Luna and V.
• V. and Mercury
• Age V.
• Craters on V.
• Earth and V.
• How hot is V.?
• Life on V.
• Mass B.
• radius B.
• V. compared to the Earth
• Size V.
• volume B.
• Opening V.
• transit B.
• V., Morning Star
• Phase B.
• The greenhouse effect B.
• axis B.
• Density B.
• Circumference B.
• Composition B.
• Geology B.
• core B.
• The interior of V.
• Inside V.
• weight on V.
• How long does it take to get to V.?
• Is there water in V.?
• climate B.
• How big is V.?
• satellites B.
• Landings on V.
• rotation B.
• Characteristics B.
• Twin Earth
• Weather on V.
• Winds on V.
• Designation for V.
• Albedo V.
• The number of moons B.
• Clouds on V.
• Q - the hottest planet?
• V. and Jupiter
• The closest planet to V.
• Origin V.
• Does V. have seasons?
• The period of rotation B.
• Connection B.
• shading B.
• sun and V.
• Retrograde V. 2009
• Retrograde V. 2010
• Who discovered V.?
• Evening Star
• What is the duration of one orbit B around the Sun?
• When was V. opened?
• What color is V.?
• Day length in V.
• The length of the year in V.
• Why is V. hotter than Mercury?
• Why is V so hot?
• Globe V.
• Research V.
• What is the age of V.?
• Facts about V.
• Collection of photographs
• magnetic field b.

The title of the article you read "Venus".

I became interested in the topic of what rotates clockwise and what against. Very often you can find a lot of things in the world based on vortices, spirals, twists, having a right spin of rotation, that is, twisted according to the gimlet rule, the right hand rule, and the left spin of rotation.

Spin is the intrinsic angular momentum of a particle. In order not to complicate the note with theory, it is better to see once. The element of the slow waltz is the right spin turn.

For many years there has been a discussion among astronomers about the direction in which spiral galaxies rotate. Do they rotate, dragging spiral branches behind them, i.e., twisting? Or do they rotate the ends of the spiral branches forward, unwinding?

At present, however, it is becoming clear that observations confirm the hypothesis of TWISTING of the spiral arms as they rotate. American physicist Michael Longo managed to confirm that most of the galaxies in the Universe are oriented to the right (right spin of rotation), i.e. rotates clockwise when viewed from its north pole.

The rotation of the solar system is counterclockwise: all planets, asteroids, comets rotate in the same direction (counterclockwise, when viewed from the north pole of the world). The sun rotates on its axis counterclockwise when viewed from the north ecliptic pole. And the Earth (like all the planets of the solar system, except for Venus and Uranus) rotates counterclockwise around its axis.

The mass of Uranus, sandwiched between the mass of Saturn and the mass of Neptune, under the influence of the rotational moment of the mass of Saturn, received a clockwise rotation. Such an impact from Saturn could occur for the reason that the mass of Saturn is 5.5 times the mass of Neptune.

Venus rotates in the opposite direction than almost all planets. The mass of the planet Earth spun the mass of the planet Venus, which received a clockwise rotation. Therefore, the daily periods of rotation of the planets of the Earth and Venus should also be close to each other.

What else is spinning and spinning?

The snail's house spins clockwise from the center (i.e., the rotation here is with a left spin turn, counterclockwise).

Tornadoes, hurricanes (winds centered in the cyclone area) blow counterclockwise in the Northern Hemisphere and are subject to centripetal force, while winds centered in the anticyclone area blow clockwise and have centrifugal force. (In the Southern Hemisphere, it's exactly the opposite.)

The DNA molecule is twisted into a right-handed double helix. This is because the backbone of the DNA double helix is ​​made up entirely of right-handed deoxyribose sugar molecules. Interestingly, during cloning, some nucleic acids change the direction of twist of their helices from right to left. On the contrary, all amino acids are twisted counterclockwise, to the left.

Flocks of bats, flying out of the caves, usually form a "right-handed" vortex. But in the caves near Karlovy Vary (Czech Republic), for some reason they circle in a counterclockwise spiral...

In one cat, at the sight of sparrows (these are her favorite birds), the tail rotates clockwise, and if these are not sparrows, but other birds, then it rotates counterclockwise.

And if we take Humanity, then we see that all sporting events (car races, horse races, running at the stadium, etc.) pass counterclockwise. After some centuries, athletes noticed that it is much more convenient to run this way. Running the stadium counterclockwise, the athlete takes a wider step with his right foot than he would have taken with his left, since the range of motion of the right leg is several centimeters larger. In most armies of the countries of the world, the turn around is carried out through the left shoulder, that is, counterclockwise; church rituals; the movement of cars on the roads in most countries of the world, with the exception of the UK, Japan and some others; at school, the letters "o", "a", "c", etc. - from the first grade they are taught to write counterclockwise. In the future, the vast majority of the adult population draws a circle, stirs the sugar in the mug with a spoon counterclockwise.

And what follows from all this? Question: Is it natural for a person to rotate counterclockwise?

As a conclusion: the Universe moves clockwise, but the solar system is against it, the physical development of all living things is clockwise, consciousness is against it.

Earth and Venus are similar in size and mass. In addition, they revolve around the Sun in very similar orbits. The size of Venus is only 650 km smaller than the size of the Earth. The mass of Venus is 81.5% of the mass of the Earth.

But that's where the similarities end. The atmosphere of Venus consists of 96.5% carbon dioxide (CO2), the temperature on the planet is absolutely unsuitable for flora and fauna, because it reaches 475 ° C. There is also very high pressure on Venus, which will crush you if you suddenly want to walk on the surface of this planet.

2. Venus is so bright that it can cast shadows.

Astronomers measure the brightness of objects in the night sky by their magnitude. Only the Sun and Moon are brighter than Venus. Its brightness can range between -3.8 and -4.6, but what is obvious is that it is always brighter than any of the brightest stars in the sky.

Venus can be so bright that it can actually cause shadows. Wait for a dark night when there is no moon in the sky and check it out for yourself.

3. The atmosphere of Venus is extremely hostile.

Although Venus is similar to Earth in size and mass, its atmosphere is unique in its own way. The mass of the atmosphere is 93 times greater than the mass of the Earth's atmosphere. If you suddenly found yourself on the surface of Venus, you would experience 92 times the pressure relative to the pressure that acts on you on Earth. This is the same as finding yourself almost a kilometer under the surface of the ocean.

And if pressure doesn't kill you, heat and toxic chemicals will certainly do. Temperatures on Venus can reach up to 475°C. Thick clouds of sulfur dioxide on Venus produce precipitation composed of sulfuric acid. It really is a hell of a place...

4. Venus rotates in the opposite direction.

While a day on Earth takes only 24 hours, a day on Venus is equal to 243 of our Earth days. But even stranger, Venus rotates in the opposite direction compared to the rest of the planets in the solar system. If you had a chance to look at the planets of the solar system from above, you would see that they all rotate counterclockwise. Except for Venus, which rotates clockwise.

5. Many missions have landed on the surface of Venus.

You probably thought that it would be impossible to land any apparatus on the surface of such a hellish world. And you are partially right. During the space race, the Soviet Union launched a series of expeditions to the surface of Venus. But engineers underestimated how terrible the planet's atmosphere is.

The first spaceships were crushed as they entered the atmosphere of Venus. But finally, the automated research space station Venera-8 became the first spacecraft that could get to the surface of Venus, take and transmit images to Earth. Subsequent missions lasted longer, and even transmitted the first color images of the surface of Venus.

6. People thought that Venus was covered with tropical forests.

Until the US and the USSR began to explore Venus through spacecraft, no one really knew what was hidden under the dense clouds of the planet. Science fiction writers have described the planet's surface as a lush tropical jungle. The hellish temperatures and dense atmosphere surprised everyone.

7. Venus has no natural satellites.

Unlike, say, Earth, Venus has no natural satellites. Mars has two, and even Pluto has. But not for Venus.

8. Venus has phases.

Looking at Venus through a telescope, you can see that the planet is in one phase or another, like the Moon. When Venus is at its closest, it actually looks like a thin crescent. As Venus grows fainter and more distant, you see a larger circle through the telescope.

9. There are several impact craters on the surface of Venus.

While the surface of Mercury, Mars and the Moon is littered with impact craters, there are relatively few craters on the surface of Venus. Experts believe that the surface of Venus is only five hundred million years old. Constant volcanism changes the surface, regularly covering any impact craters.

We have been studying the solar system for hundreds of years, and one would assume that we have the answers to all the frequently asked questions about it. Why the planets rotate, why they are in such orbits, why the Moon does not fall to the Earth… But we cannot boast of this. To see this, just look at our neighbor, Venus.

Scientists began to study it closely in the middle of the last century, and at first it seemed relatively dull and of little interest. However, it soon became clear that this is the most natural hell with acid rain, which also rotates in the opposite direction! More than half a century has passed since then. We've learned a lot about Venus's climate, but we still haven't been able to figure out why it doesn't spin like everyone else. Although there are many hypotheses in this regard.

In astronomy, rotation in the opposite direction is called retrograde. Since the entire solar system was formed from one rotating gas cloud, all the planets move in orbits in the same direction - counterclockwise, if you look at this whole picture from above, from the north pole of the Earth. In addition, these celestial bodies also rotate around their own axis - also counterclockwise. But this does not apply to the two planets of our system - Venus and Uranus.

Uranus is actually lying on its side, most likely due to a couple of collisions with large objects. Venus, on the other hand, rotates clockwise, and explaining this is even more problematic. One of the early hypotheses suggested that Venus collided with an asteroid, and the impact was so strong that the planet began to spin in the opposite direction. This theory was thrown into the discussion of the interested public in 1965 by two astronomers who processed radar data. Moreover, the definition of “thrown in” is by no means a humiliation. As the scientists themselves stated, the quote: “This possibility is dictated only by the imagination. It is hardly possible to obtain evidence confirming it.” Extremely convincing, isn't it? Be that as it may, this hypothesis does not stand up to the test of simple mathematics - it turns out that an object whose size is sufficient to reverse the rotation of Venus will simply destroy the planet. Its kinetic energy will be 10,000 times more than what it takes to smash the planet to dust. In this regard, the hypothesis was sent to the distant shelves of scientific libraries.

It was replaced by several theories based on some evidence base. One of the most popular, proposed in 1970, suggested that Venus originally rotated in this way. It just turned upside down at some point in its history! This could be due to the processes that took place inside Venus and in its atmosphere.

This planet, like the Earth, is multi-layered. Here, too, there is a core, mantle and crust. During the rotation of the planet, the core and mantle experience friction in the area of ​​​​their contact. The atmosphere of Venus is very thick, and, thanks to the heat and attraction of the Sun, it is subjected, like the rest of the planet, to the tidal influence of our luminary. According to the described hypothesis, the friction of the crust with the mantle, coupled with atmospheric tidal oscillations, created a torque, and Venus, having lost stability, capsized. The simulations performed showed that this could only happen if Venus had an axial tilt of about 90 degrees since its formation. Later this number decreased somewhat. In any case, this is a highly unusual hypothesis. Just imagine - a tumbling planet! This is some kind of circus, not space.

In 1964, a hypothesis was put forward, according to which Venus changed its rotation gradually - it slowed down, stopped, and began to spin in the other direction. This could be triggered by several factors, including interactions with the Sun's magnetic field, atmospheric tides, or a combination of several forces. The atmosphere of Venus, according to this theory, spun in the opposite direction of the first. This created a force that first slowed Venus and then spun it retrograde. As a bonus, this hypothesis also explains the long duration of the day on the planet.

In the dispute between the last two explanations, there is no clear favorite yet. To understand which one to prefer, we need to know much more about the dynamics of early Venus, in particular about its rotation rate and axial tilt. According to an article published in 2001 in the journal Nature, Venus is more likely to tip over if it has a higher initial rotational speed. But, if it was less than one revolution in 96 hours with a slight axial tilt (less than 70 degrees), the second hypothesis looks more plausible. Unfortunately, it is quite difficult for scientists to look into the past four billion years. Therefore, until we invent a time machine or run unrealistically high-quality computer simulations today, progress in this matter is not expected.

It is clear that this is not a complete description of the discussion concerning the rotation of Venus. So, for example, the very first of the hypotheses we described, the one that comes from 1965, received an unexpected development not so long ago. In 2008, it was suggested that our neighbor could spin in the opposite direction at a time when she was still a small unintelligent planetesimal. An object about the same size as Venus itself should have crashed into it. Instead of the destruction of Venus, the merging of two celestial bodies into one full-fledged planet would follow. The main difference from the original hypothesis here is that scientists may have evidence in favor of this turn of the situation.

According to what we know about the topography of Venus, there is very little water on it. Compared to Earth, of course. Moisture could disappear from there as a result of a catastrophic collision of cosmic bodies. That is, this hypothesis would also explain the dryness of Venus. Although there are also, no matter how ironic it may sound in this case, pitfalls. Water from the surface of the planet could simply evaporate under the rays of the Sun, which is hot here. To clarify this issue, a mineralogical analysis of rocks from the surface of Venus is needed. If water is present in them, the hypothesis of an early collision will disappear. The problem is that such analyzes have not yet been carried out. Venus is extremely unfriendly to the robots that we send to her. Destroys without any hesitation.

Be that as it may, building an interplanetary station with a rover capable of working here is still easier than a time machine. So let's not lose hope. Perhaps humanity will receive an answer to the riddle about the “wrong” rotation of Venus even during our lifetime.