Every literate person should know not only that the planet is surrounded by an atmosphere made of a mixture of all kinds of gases, but also that there are different layers of the atmosphere that are located at unequal distances from the Earth’s surface.

Observing the sky, we do not see at all its complex structure, its heterogeneous composition, or other things hidden from view. But it is precisely thanks to the complex and multicomponent composition of the air layer that conditions exist around the planet that allowed life to arise here, vegetation to flourish, and everything that has ever been here to appear.

Knowledge about the subject of conversation is given to people already in the 6th grade at school, but some have not yet completed their studies, and some have been there so long ago that they have already forgotten everything. Nevertheless, every educated person should know what the world around him consists of, especially that part of it on which the very possibility of his normal life directly depends.

What is the name of each layer of the atmosphere, at what altitude is it located, what role does it play? All these issues will be discussed below.

The structure of the Earth's atmosphere

Looking at the sky, especially when it is completely cloudless, it is very difficult to even imagine that it has such a complex and multi-layered structure, that the temperature there at different altitudes is very different, and that it is there, at altitude, that the most important processes take place for all flora and fauna on the ground.

If it were not for such a complex composition of the gas cover of the planet, then there would simply be no life here and even the possibility for its origin.

The first attempts to study this part of the surrounding world were made by the ancient Greeks, but they could not go too far in their conclusions, since they did not have the necessary technical base. They did not see the boundaries of different layers, could not measure their temperature, study their component composition, etc.

Basically, only weather phenomena prompted the most progressive minds to think that the visible sky is not as simple as it seems.

It is believed that the structure of the modern gas shell around the Earth was formed in three stages. First there was a primordial atmosphere of hydrogen and helium captured from outer space.

Then volcanic eruptions filled the air with a mass of other particles, and a secondary atmosphere arose. After passing all the basic chemical reactions and particle relaxation processes, the current situation arose.

Layers of the atmosphere in order from the surface of the earth and their characteristics

The structure of the gas shell of the planet is quite complex and diverse. Let's look at it in more detail, gradually reaching the highest levels.

Troposphere

Apart from the boundary layer, the troposphere is the lowest layer of the atmosphere. It extends to a height of approximately 8-10 km above the earth's surface in polar regions, 10-12 km in temperate climates, and 16-18 km in tropical parts.

Interesting fact: this distance may vary depending on the time of year - in winter it is slightly less than in summer.

The air of the troposphere contains the main life-giving force for all life on earth. It contains about 80% of all available atmospheric air, more than 90% of water vapor, this is where clouds, cyclones and others form atmospheric phenomena.

It is interesting to note the gradual decrease in temperature as you rise from the surface of the planet. Scientists have calculated that for every 100 m of altitude, the temperature decreases by about 0.6-0.7 degrees.

Stratosphere

The next most important layer is the stratosphere. The height of the stratosphere is approximately 45-50 kilometers. It starts at 11 km and negative temperatures already prevail here, reaching as much as -57°C.

Why is this layer important for humans, all animals and plants? It is here, at an altitude of 20-25 kilometers, that the ozone layer is located - it traps ultraviolet rays emanating from the sun and reduces their destructive effect on flora and fauna to an acceptable level.

It is very interesting to note that the stratosphere absorbs many types of radiation that come to the earth from the sun, other stars and outer space. The energy received from these particles is used to ionize the molecules and atoms located here, and various chemical compounds appear.

All this leads to such a famous and colorful phenomenon as the northern lights.

Mesosphere

The mesosphere begins at about 50 and extends to 90 kilometers. The gradient, or temperature difference with changes in altitude, is no longer as large here as in the lower layers. At the upper boundaries of this shell the temperature is about -80°C. The composition of this area includes approximately 80% nitrogen as well as 20% oxygen.

It is important to note that the mesosphere is a kind of dead zone for any flying devices. Airplanes cannot fly here, since the air is too thin, and satellites cannot fly at such a low altitude, since the available air density for them is very high.

Another one interesting characteristic mesosphere – This is where meteorites that strike the planet burn up. The study of such layers distant from the earth occurs with the help of special rockets, but the efficiency of the process is low, so the knowledge of the region leaves much to be desired.

Thermosphere

Immediately after the considered layer comes the thermosphere, whose altitude in kilometers extends for as much as 800 km. In some ways, this is almost outer space. Here there is an aggressive impact of cosmic radiation, radiation, solar radiation.

All this gives rise to such a wonderful and beautiful phenomenon as the aurora.

The lowest layer of the thermosphere is heated to temperatures of approximately 200 K or more. This happens due to elementary processes between atoms and molecules, their recombination and radiation.

The upper layers are heated due to the flowing here magnetic storms, electric currents, which are generated in this case. The temperature of the layer is uneven and can fluctuate very significantly.

Most flights occur in the thermosphere artificial satellites, ballistic bodies, manned stations, etc.

Also, launch tests of various types of weapons and missiles are carried out here.

Exosphere The exosphere, or as it is also called the scattering sphere, is the highest level of our atmosphere, its limit, followed by the interplanetary. space

The exosphere begins at an altitude of approximately 800-1000 kilometers.

The dense layers are left behind and here the air is extremely rarefied; any particles that enter from the outside are simply carried away into space due to the very weak effect of gravity. This shell ends at an altitude of approximately 3000-3500 km

, and there are almost no particles here anymore. This zone is called the near-space vacuum. What predominates here is not individual particles in their normal state, but plasma, most often completely ionized.

The importance of the atmosphere in the life of the Earth

This is what all the main levels of the atmosphere of our planet look like. Its detailed scheme may include other regions, but they are of secondary importance. It's important to note that A lot of ozone in its stratosphere allows flora and fauna to escape from the deadly effects of radiation and radiation from space.

It is also here that the weather is formed, all atmospheric phenomena occur, cyclones and winds arise and die, and this or that pressure is established. All this has a direct impact on the condition of humans, all living organisms and plants.

The nearest layer, the troposphere, gives us the opportunity to breathe, saturates all living things with oxygen and allows them to live. Even small deviations in the structure and component composition of the atmosphere can have the most detrimental effect on all living things.

That is why such a campaign against harmful emissions from cars and production, environmentalists are sounding the alarm about the thickness of the ozone layer, the Green Party and others like it are advocating for maximum conservation of nature. This is the only way to prolong normal life on earth and not make it unbearable in terms of climate.

Everyone who has flown on an airplane is accustomed to this kind of message: “our flight takes place at an altitude of 10,000 m, the temperature outside is 50 ° C.” It seems nothing special. The farther from the surface of the Earth heated by the Sun, the colder it is. Many people think that the temperature decreases continuously with altitude and that the temperature gradually drops, approaching the temperature of space. By the way, scientists thought so until the end of the 19th century.

Let's take a closer look at the distribution of air temperature over the Earth. The atmosphere is divided into several layers, which primarily reflect the nature of temperature changes.

The lower layer of the atmosphere is called troposphere, which means "sphere of rotation." All changes in weather and climate are the result physical processes, occurring precisely in this layer. The upper boundary of this layer is located where the decrease in temperature with height is replaced by its increase - approximately at an altitude of 15-16 km above the equator and 7-8 km above the poles. Like the Earth itself, the atmosphere, under the influence of the rotation of our planet, is also somewhat flattened over the poles and swells over the equator. However, this effect is expressed much more strongly in the atmosphere than in the solid shell of the Earth. In the direction from the Earth's surface to the upper boundary of the troposphere, the air temperature decreases. Above the equator, the minimum air temperature is about -62°C, and above the poles about -45°C. At temperate latitudes, more than 75% of the mass of the atmosphere is in the troposphere. In the tropics, about 90% of the mass of the atmosphere is located within the troposphere.

In 1899, a minimum was found in the vertical temperature profile at a certain altitude, and then the temperature increased slightly. The beginning of this increase means the transition to the next layer of the atmosphere - to stratosphere, which means “layer sphere.” The term stratosphere means and reflects the previous idea of ​​​​the uniqueness of the layer lying above the troposphere. The stratosphere extends to an altitude of about 50 km above the earth’s surface. Its peculiarity is, in particular, a sharp increase in air temperature. This increase in temperature is explained ozone formation reaction is one of the main chemical reactions occurring in the atmosphere.

The bulk of ozone is concentrated at altitudes of approximately 25 km, but in general the ozone layer is a highly extended shell, covering almost the entire stratosphere. The interaction of oxygen with ultraviolet rays is one of the beneficial processes in the earth’s atmosphere that contributes to the maintenance of life on Earth. The absorption of this energy by ozone prevents its excessive flow to the earth's surface, where exactly the level of energy that is suitable for the existence of terrestrial life forms is created. The ozonosphere absorbs some of the radiant energy passing through the atmosphere. As a result, a vertical air temperature gradient of approximately 0.62°C per 100 m is established in the ozonosphere, i.e., the temperature increases with altitude up to the upper limit of the stratosphere - the stratopause (50 km), reaching, according to some data, 0°C.

At altitudes from 50 to 80 km there is a layer of the atmosphere called mesosphere. The word "mesosphere" means "intermediate sphere", where the air temperature continues to decrease with height. Above the mesosphere, in a layer called thermosphere, the temperature rises again with altitude up to about 1000°C, and then drops very quickly to -96°C. However, it does not drop indefinitely, then the temperature increases again.

Thermosphere is the first layer ionosphere. Unlike the previously mentioned layers, the ionosphere is not distinguished by temperature. The ionosphere is an area of ​​electrical nature that makes many types of radio communications possible. The ionosphere is divided into several layers, designated by the letters D, E, F1 and F2. These layers also have special names. The separation into layers is caused by several reasons, among which the most important is the unequal influence of the layers on the passage of radio waves. The lowest layer, D, mainly absorbs radio waves and thereby prevents their further propagation. The best studied layer E is located at an altitude of approximately 100 km above the earth's surface. It is also called the Kennelly-Heaviside layer after the names of the American and English scientists who simultaneously and independently discovered it. Layer E, like a giant mirror, reflects radio waves. Thanks to this layer, long radio waves travel further distances than would be expected if they propagated only in a straight line, without being reflected from the E layer. The F layer has similar properties. It is also called the Appleton layer. Together with the Kennelly-Heaviside layer, it reflects radio waves to terrestrial radio stations. Such reflection can occur at various angles. The Appleton layer is located at an altitude of about 240 km.

The outermost region of the atmosphere, the second layer of the ionosphere, is often called exosphere. This term refers to the existence of the outskirts of space near the Earth. It is difficult to determine exactly where the atmosphere ends and space begins, since with altitude the density of atmospheric gases gradually decreases and the atmosphere itself gradually turns into almost a vacuum, in which only individual molecules are found. Already at an altitude of approximately 320 km, the density of the atmosphere is so low that molecules can travel more than 1 km without colliding with each other. The outermost part of the atmosphere serves as its upper boundary, which is located at altitudes from 480 to 960 km.

More information about processes in the atmosphere can be found on the website “Earth Climate”

At 0 °C - 1.0048·10 3 J/(kg·K), C v - 0.7159·10 3 J/(kg·K) (at 0 °C). Solubility of air in water (by mass) at 0 °C - 0.0036%, at 25 °C - 0.0023%.

In addition to the gases indicated in the table, the atmosphere contains Cl 2, SO 2, NH 3, CO, O 3, NO 2, hydrocarbons, HCl, HBr, vapors, I 2, Br 2, as well as many other gases in minor amounts quantities. The troposphere constantly contains a large amount of suspended solid and liquid particles (aerosol). The rarest gas in the Earth's atmosphere is radon (Rn).

The structure of the atmosphere

Atmospheric boundary layer

The lower layer of the atmosphere adjacent to the Earth's surface (1-2 km thick) in which the influence of this surface directly affects its dynamics.

Troposphere

Its upper limit is at an altitude of 8-10 km in polar, 10-12 km in temperate and 16-18 km in tropical latitudes; lower in winter than in summer. The lower, main layer of the atmosphere contains more than 80% of the total mass of atmospheric air and about 90% of the total water vapor present in the atmosphere. Turbulence and convection are highly developed in the troposphere, clouds appear, and cyclones and anticyclones develop. Temperature decreases with increasing altitude with an average vertical gradient of 0.65°/100 m

Tropopause

The transition layer from the troposphere to the stratosphere, a layer of the atmosphere in which the decrease in temperature with height stops.

Stratosphere

A layer of the atmosphere located at an altitude of 11 to 50 km. Characterized by a slight change in temperature in the 11-25 km layer (lower layer of the stratosphere) and an increase in temperature in the 25-40 km layer from −56.5 to 0.8 ° (upper layer of the stratosphere or inversion region). Having reached a value of about 273 K (almost 0 °C) at an altitude of about 40 km, the temperature remains constant up to an altitude of about 55 km. This region of constant temperature is called the stratopause and is the boundary between the stratosphere and mesosphere.

Stratopause

The boundary layer of the atmosphere between the stratosphere and mesosphere. In the vertical temperature distribution there is a maximum (about 0 °C).

Mesosphere

The mesosphere begins at an altitude of 50 km and extends to 80-90 km. Temperature decreases with height with an average vertical gradient of (0.25-0.3)°/100 m. The main energy process is radiant heat transfer. Complex photochemical processes involving free radicals, vibrationally excited molecules, etc. cause the glow of the atmosphere.

Mesopause

Transitional layer between the mesosphere and thermosphere. There is a minimum in the vertical temperature distribution (about -90 °C).

Karman Line

The height above sea level, which is conventionally accepted as the boundary between the Earth's atmosphere and space. According to the FAI definition, the Karman line is located at an altitude of 100 km above sea level.

Thermosphere

The upper limit is about 800 km. The temperature rises to altitudes of 200-300 km, where it reaches values ​​of the order of 1226.85 C, after which it remains almost constant to high altitudes. Under the influence of solar radiation and cosmic radiation, ionization of the air (“ auroras”) occurs - the main regions of the ionosphere lie inside the thermosphere. At altitudes above 300 km, atomic oxygen predominates. The upper limit of the thermosphere is largely determined by the current activity of the Sun. During periods of low activity - for example, in 2008-2009 - there is a noticeable decrease in the size of this layer.

Thermopause

The region of the atmosphere adjacent above the thermosphere. In this region, the absorption of solar radiation is negligible and the temperature does not actually change with altitude.

Exosphere (scattering sphere)

Up to an altitude of 100 km, the atmosphere is a homogeneous, well-mixed mixture of gases. In higher layers, the distribution of gases by height depends on their molecular weights; the concentration of heavier gases decreases faster with distance from the Earth's surface. Due to the decrease in gas density, the temperature drops from 0 °C in the stratosphere to −110 °C in the mesosphere. However kinetic energy individual particles at altitudes of 200-250 km correspond to a temperature of ~150 °C. Above 200 km, significant fluctuations in temperature and gas density in time and space are observed.

At an altitude of about 2000-3500 km, the exosphere gradually turns into the so-called near space vacuum, which is filled with highly rarefied particles of interplanetary gas, mainly hydrogen atoms. But this gas represents only part of the interplanetary matter. The other part consists of dust particles of cometary and meteoric origin. In addition to extremely rarefied dust particles, electromagnetic and corpuscular radiation of solar and galactic origin penetrates into this space.

Review

The troposphere accounts for about 80% of the mass of the atmosphere, the stratosphere - about 20%; the mass of the mesosphere is no more than 0.3%, the thermosphere is less than 0.05% of the total mass of the atmosphere.

Based on electrical properties in the atmosphere, they distinguish neutrosphere And ionosphere .

Depending on the composition of the gas in the atmosphere, they emit homosphere And heterosphere. Heterosphere- This is the area where gravity affects the separation of gases, since their mixing at such an altitude is negligible. This implies a variable composition of the heterosphere. Below it lies a well-mixed, homogeneous part of the atmosphere, called the homosphere. The boundary between these layers is called the turbopause, it lies at an altitude of about 120 km.

Other properties of the atmosphere and effects on the human body

Already at an altitude of 5 km above sea level, an untrained person begins to experience oxygen starvation and without adaptation, a person’s performance is significantly reduced. The physiological zone of the atmosphere ends here. Human breathing becomes impossible at an altitude of 9 km, although up to approximately 115 km the atmosphere contains oxygen.

The atmosphere supplies us with the oxygen necessary for breathing. However, due to the drop in the total pressure of the atmosphere, as you rise to altitude, the partial pressure of oxygen decreases accordingly.

In rarefied layers of air, sound propagation is impossible. Up to altitudes of 60-90 km, it is still possible to use air resistance and lift for controlled aerodynamic flight. But starting from altitudes of 100-130 km, the concepts of the M number and the sound barrier, familiar to every pilot, lose their meaning: there passes the conventional Karman line, beyond which the region of purely ballistic flight begins, which can only be controlled using reactive forces.

At altitudes above 100 km, the atmosphere is deprived of another remarkable property - the ability to absorb, conduct and transmit thermal energy by convection (that is, by mixing air). It means that various elements equipment, orbital equipment space station will not be able to cool outside in the way that is usually done on an airplane - with the help of air jets and air radiators. At this altitude, as in space generally, the only way to transfer heat is thermal radiation.

History of atmospheric formation

According to the most common theory, the Earth's atmosphere has had three different compositions throughout its history. Initially, it consisted of light gases (hydrogen and helium) captured from interplanetary space. This is the so-called primary atmosphere. At the next stage, active volcanic activity led to the saturation of the atmosphere with gases other than hydrogen (carbon dioxide, ammonia, water vapor). This is how it was formed secondary atmosphere. This atmosphere was restorative. Further, the process of atmosphere formation was determined by the following factors:

• leakage of light gases (hydrogen and helium) into interplanetary space;
• chemical reactions occurring in the atmosphere under the influence ultraviolet radiation, lightning discharges and some other factors.

Gradually these factors led to the formation tertiary atmosphere, characterized by a much lower content of hydrogen and a much higher content of nitrogen and carbon dioxide (formed as a result of chemical reactions from ammonia and hydrocarbons).

Nitrogen

Education large quantity nitrogen N 2 is due to the oxidation of the ammonia-hydrogen atmosphere by molecular oxygen O 2, which began to come from the surface of the planet as a result of photosynthesis, starting 3 billion years ago. Nitrogen N2 is also released into the atmosphere as a result of denitrification of nitrates and other nitrogen-containing compounds. Nitrogen is oxidized by ozone to NO in the upper atmosphere.

Nitrogen N 2 reacts only under specific conditions (for example, during a lightning discharge). The oxidation of molecular nitrogen by ozone during electrical discharges is used in small quantities in the industrial production of nitrogen fertilizers. Cyanobacteria (blue-green algae) and nodule bacteria, which form rhizobial symbiosis with leguminous plants, which can be effective green manures - plants that do not deplete, but enrich the soil with natural fertilizers, can oxidize it with low energy consumption and convert it into a biologically active form.

Oxygen

The composition of the atmosphere began to change radically with the appearance of living organisms on Earth, as a result of photosynthesis, accompanied by the release of oxygen and the absorption of carbon dioxide. Initially, oxygen was spent on the oxidation of reduced compounds - ammonia, hydrocarbons, ferrous form of iron contained in the oceans, etc. At the end of this stage, the oxygen content in the atmosphere began to increase. Gradually, a modern atmosphere with oxidizing properties formed. Since this caused serious and abrupt changes in many processes occurring in the atmosphere, lithosphere and biosphere, this event was called the Oxygen Catastrophe.

Noble gases

Air pollution

IN Lately Man began to influence the evolution of the atmosphere. The result human activity became constant growth the content of carbon dioxide in the atmosphere due to the combustion of hydrocarbon fuels accumulated in previous geological eras. Huge amounts of CO 2 are consumed during photosynthesis and absorbed by the world's oceans. This gas enters the atmosphere due to the decomposition of carbonate rocks And organic matter plant and animal origin, as well as due to volcanism and human industrial activity. Over the past 100 years, the content of CO 2 in the atmosphere has increased by 10%, with the bulk (360 billion tons) coming from fuel combustion. If the growth rate of fuel combustion continues, then in the next 200-300 years the amount of CO 2 in the atmosphere will double and could lead to global climate change.

Fuel combustion is the main source of polluting gases (CO, SO2). Sulfur dioxide is oxidized by atmospheric oxygen to SO 3, and nitrogen oxide to NO 2 in the upper layers of the atmosphere, which in turn interact with water vapor, and the resulting sulfuric acid H 2 SO 4 and nitric acid HNO 3 fall to the surface of the Earth in the form so-called acid rain. The use of internal combustion engines leads to significant atmospheric pollution with nitrogen oxides, hydrocarbons and lead compounds (tetraethyl lead Pb(CH 3 CH 2) 4).

Aerosol pollution of the atmosphere is due to both natural causes (volcanic eruptions, dust storms, entrainment of droplets sea ​​water and plant pollen, etc.), and economic activity humans (mining ores and building materials, burning fuel, making cement, etc.). Intensive large-scale emission of solid particles into the atmosphere is one of the possible reasons changes in the planet's climate.

see also

• Jacchia (atmosphere model)

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Notes

1. M. I. Budyko, K. Ya. Kondratiev Atmosphere of the Earth // Great Soviet Encyclopedia. 3rd ed. / Ch. ed. A. M. Prokhorov. - M.: Soviet Encyclopedia, 1970. - T. 2. Angola - Barzas. - pp. 380-384.
2. - article from the Geological Encyclopedia
4. Gribbin, John. Science. A History (1543-2001). - L.: Penguin Books, 2003. - 648 p. - ISBN 978-0-140-29741-6.
5. Tans, Pieter. Globally averaged marine surface annual mean data. NOAA/ESRL. Retrieved February 19, 2014.(English) (as of 2013)
6. IPCC (English) (as of 1998).
7. S. P. Khromov Air humidity // Great Soviet Encyclopedia. 3rd ed. / Ch. ed. A. M. Prokhorov. - M.: Soviet Encyclopedia, 1971. - T. 5. Veshin - Gazli. - P. 149.
8. (English) SpaceDaily, 07/16/2010

Literature

1. V. V. Parin, F. P. Kosmolinsky, B. A. Dushkov“Space biology and medicine” (2nd edition, revised and expanded), M.: “Prosveshcheniye”, 1975, 223 pp.
2. N. V. Gusakova"Chemistry environment", Rostov-on-Don: Phoenix, 2004, 192 with ISBN 5-222-05386-5
3. Sokolov V. A. Geochemistry natural gases, M., 1971;
4. McEwen M., Phillips L. Atmospheric Chemistry, M., 1978;
5. Wark K., Warner S. Air pollution. Sources and control, trans. from English, M.. 1980;
6. Monitoring of background pollution of natural environments. V. 1, L., 1982.

Links

• // December 17, 2013, FOBOS Center

History of the Earth Physical properties of the Earth Shells of the Earth Geography and geology Environment see also

Excerpt characterizing the Earth's Atmosphere

When Pierre approached them, he noticed that Vera was in a smug rapture of conversation, Prince Andrei (which rarely happened to him) seemed embarrassed.
– What do you think? – Vera said with a subtle smile. “You, prince, are so insightful and so immediately understand the character of people.” What do you think about Natalie, can she be constant in her affections, can she, like other women (Vera meant herself), love a person once and remain faithful to him forever? This is what I think true love. What do you think, prince?
“I know your sister too little,” answered Prince Andrei with a mocking smile, under which he wanted to hide his embarrassment, “to resolve such a delicate question; and then I noticed that the less I like a woman, the more constant she is,” he added and looked at Pierre, who came up to them at that time.
- Yes, it’s true, prince; in our time,” Vera continued (mentioning our time, as narrow-minded people generally like to mention, believing that they have found and appreciated the features of our time and that the properties of people change over time), in our time a girl has so much freedom that le plaisir d"etre courtisee [the pleasure of having admirers] often drowns out the true feeling in her. Et Nathalie, il faut l"avouer, y est tres sensible. [And Natalya, I must admit, is very sensitive to this.] The return to Natalie again made Prince Andrei frown unpleasantly; he wanted to get up, but Vera continued with an even more refined smile.
“I think no one was courtisee [the object of courtship] like her,” Vera said; - but never, until very recently, did she seriously like anyone. “You know, Count,” she turned to Pierre, “even our dear cousin Boris, who was, entre nous [between us], very, very dans le pays du tendre... [in the land of tenderness...]
Prince Andrei frowned and remained silent.
– You’re friends with Boris, aren’t you? - Vera told him.
- Yes, I know him…
– Did he tell you correctly about his childhood love for Natasha?
– Was there childhood love? - Prince Andrei suddenly asked, blushing unexpectedly.
- Yes. Vous savez entre cousin et cousine cette intimate mene quelquefois a l"amour: le cousinage est un dangereux voisinage, N"est ce pas? [You know, between a cousin and sister, this closeness sometimes leads to love. Such kinship is a dangerous neighborhood. Is not it?]
“Oh, without a doubt,” said Prince Andrei, and suddenly, unnaturally animated, he began joking with Pierre about how he should be careful in his treatment of his 50-year-old Moscow cousins, and in the middle of the joking conversation he stood up and, taking under Pierre's arm and took him aside.
- Well? - said Pierre, looking with surprise at the strange animation of his friend and noticing the look that he cast at Natasha as he stood up.
“I need, I need to talk to you,” said Prince Andrei. – You know our women’s gloves (he was talking about those Masonic gloves that were given to a newly elected brother to give to his beloved woman). “I... But no, I’ll talk to you later...” And with a strange sparkle in his eyes and anxiety in his movements, Prince Andrei approached Natasha and sat down next to her. Pierre saw Prince Andrei ask her something, and she flushed and answered him.
But at this time Berg approached Pierre, urgently asking him to take part in the dispute between the general and the colonel about Spanish affairs.
Berg was pleased and happy. The smile of joy did not leave his face. The evening was very good and exactly like other evenings he had seen. Everything was similar. And ladies', delicate conversations, and cards, and a general at cards, raising his voice, and a samovar, and cookies; but one thing was still missing, something that he always saw at the evenings, which he wanted to imitate.
There was a lack of loud conversation between men and an argument about something important and smart. The general started this conversation and Berg attracted Pierre to him.

The next day, Prince Andrei went to the Rostovs for dinner, as Count Ilya Andreich called him, and spent the whole day with them.
Everyone in the house felt for whom Prince Andrei was traveling, and he, without hiding, tried to be with Natasha all day. Not only in Natasha’s frightened, but happy and enthusiastic soul, but in the whole house one could feel the fear of something important that was about to happen. The Countess looked at Prince Andrei with sad and seriously stern eyes when he spoke to Natasha, and timidly and feignedly began some insignificant conversation as soon as he looked back at her. Sonya was afraid to leave Natasha and was afraid to be a hindrance when she was with them. Natasha turned pale with fear of anticipation when she remained alone with him for minutes. Prince Andrei amazed her with his timidity. She felt that he needed to tell her something, but that he could not bring himself to do so.
When Prince Andrey left in the evening, the Countess came up to Natasha and said in a whisper:
- Well?
“Mom, for God’s sake don’t ask me anything now.” “You can’t say that,” Natasha said.
But despite this, that evening Natasha, sometimes excited, sometimes frightened, with fixed eyes, lay for a long time in her mother’s bed. Either she told her how he praised her, then how he said that he would go abroad, then how he asked where they would live this summer, then how he asked her about Boris.
- But this, this... has never happened to me! - she said. “Only I’m scared in front of him, I’m always scared in front of him, what does that mean?” That means it's real, right? Mom, are you sleeping?
“No, my soul, I’m scared myself,” answered the mother. - Go.
“I won’t sleep anyway.” What nonsense is it to sleep? Mom, mom, this has never happened to me! - she said with surprise and fear at the feeling that she recognized in herself. – And could we think!...
It seemed to Natasha that even when she first saw Prince Andrey in Otradnoye, she fell in love with him. She seemed to be frightened by this strange, unexpected happiness, that the one whom she had chosen back then (she was firmly convinced of this), that the same one had now met her again, and, it seemed, was not indifferent to her. “And he had to come to St. Petersburg on purpose now that we are here. And we had to meet at this ball. It's all fate. It is clear that this is fate, that all this was leading to this. Even then, as soon as I saw him, I felt something special.”
- What else did he tell you? What verses are these? Read... - the mother said thoughtfully, asking about the poems that Prince Andrei wrote in Natasha’s album.
“Mom, isn’t it a shame that he’s a widower?”
- That's enough, Natasha. Pray to God. Les Marieiages se font dans les cieux. [Marriages are made in heaven.]
- Darling, mother, how I love you, how good it makes me feel! – Natasha shouted, crying tears of happiness and excitement and hugging her mother.
At the same time, Prince Andrei was sitting with Pierre and telling him about his love for Natasha and his firm intention to marry her.

On this day, Countess Elena Vasilyevna had a reception, there was a French envoy, there was a prince, who had recently become a frequent visitor to the countess’s house, and many brilliant ladies and men. Pierre was downstairs, walked through the halls, and amazed all the guests with his concentrated, absent-minded and gloomy appearance.
Since the time of the ball, Pierre had felt the approaching attacks of hypochondria and with desperate effort tried to fight against them. From the time the prince became close to his wife, Pierre was unexpectedly granted a chamberlain, and from that time on he began to feel heaviness and shame in large society, and more often the old gloomy thoughts about the futility of everything human began to come to him. At the same time, the feeling he noticed between Natasha, whom he protected, and Prince Andrei, the contrast between his position and the position of his friend, further intensified this gloomy mood. He equally tried to avoid thoughts about his wife and about Natasha and Prince Andrei. Again everything seemed insignificant to him in comparison with eternity, again the question presented itself: “why?” And he forced himself to work day and night on Masonic works, hoping to ward off the approach of the evil spirit. Pierre, at 12 o'clock, having left the countess's chambers, was sitting upstairs in a smoky, low room, in a worn dressing gown in front of the table, copying out authentic Scottish acts, when someone entered his room. It was Prince Andrei.
“Oh, it’s you,” said Pierre with an absent-minded and dissatisfied look. “And I’m working,” he said, pointing to a notebook with that look of salvation from the hardships of life with which unhappy people look at their work.
Prince Andrei, with a radiant, enthusiastic face and renewed life, stopped in front of Pierre and, not noticing his sad face, smiled at him with the egoism of happiness.
“Well, my soul,” he said, “yesterday I wanted to tell you and today I came to you for this.” I've never experienced anything like it. I'm in love, my friend.
Pierre suddenly sighed heavily and collapsed with his heavy body on the sofa, next to Prince Andrei.
- To Natasha Rostova, right? - he said.
- Yes, yes, who? I would never believe it, but this feeling is stronger than me. Yesterday I suffered, I suffered, but I wouldn’t give up this torment for anything in the world. I haven't lived before. Now only I live, but I can't live without her. But can she love me?... I'm too old for her... What aren't you saying?...
- I? I? “What did I tell you,” Pierre suddenly said, getting up and starting to walk around the room. - I always thought this... This girl is such a treasure, such... This is a rare girl... Dear friend, I ask you, don’t get smart, don’t doubt, get married, get married and get married... And I’m sure that there will be no happier person than you.
- But she!
- She loves you.
“Don’t talk nonsense...” said Prince Andrei, smiling and looking into Pierre’s eyes.
“He loves me, I know,” Pierre shouted angrily.
“No, listen,” said Prince Andrei, stopping him by the hand. – Do you know what situation I’m in? I need to tell everything to someone.
“Well, well, say, I’m very glad,” said Pierre, and indeed his face changed, the wrinkles smoothed out, and he joyfully listened to Prince Andrei. Prince Andrei seemed and was a completely different, new person. Where was his melancholy, his contempt for life, his disappointment? Pierre was the only person to whom he dared to speak; but he expressed to him everything that was in his soul. Either he easily and boldly made plans for a long future, talked about how he could not sacrifice his happiness for the whim of his father, how he would force his father to agree to this marriage and love her or do without his consent, then he was surprised how something strange, alien, independent of him, influenced by the feeling that possessed him.
“I wouldn’t believe anyone who told me that I could love like that,” said Prince Andrei. “This is not at all the feeling that I had before.” The whole world is divided for me into two halves: one - she and there is all the happiness of hope, light; the other half is everything where she is not there, there is all despondency and darkness...
“Darkness and gloom,” Pierre repeated, “yes, yes, I understand that.”
– I can’t help but love the world, it’s not my fault. And I'm very happy. You understand me? I know you're happy for me.
“Yes, yes,” Pierre confirmed, looking at his friend with tender and sad eyes. The brighter the fate of Prince Andrei seemed to him, the darker his own seemed.

To get married, the consent of the father was needed, and for this, the next day, Prince Andrei went to his father.
The father, with outward calm but inner anger, accepted his son's message. He could not understand that anyone would want to change life, to introduce something new into it, when life was already ending for him. “If only they would let me live the way I want, and then we would do what we wanted,” the old man said to himself. With his son, however, he used the diplomacy that he used on important occasions. Taking a calm tone, he discussed the whole matter.
Firstly, the marriage was not brilliant in terms of kinship, wealth and nobility. Secondly, Prince Andrei was not in his first youth and was in poor health (the old man was especially careful about this), and she was very young. Thirdly, there was a son whom it was a pity to give to the girl. Fourthly, finally,” said the father, looking mockingly at his son, “I ask you, postpone the matter for a year, go abroad, get treatment, find, as you want, a German for Prince Nikolai, and then, if it’s love, passion, stubbornness, whatever you want, so great, then get married.
“And this is my last word, you know, my last...” the prince finished in a tone that showed that nothing would force him to change his decision.
Prince Andrei clearly saw that the old man hoped that the feeling of him or his future bride would not withstand the test of the year, or that he himself, the old prince, would die by this time, and decided to fulfill his father’s will: to propose and postpone the wedding for a year.
Three weeks after his last evening at the Rostovs, Prince Andrei returned to St. Petersburg.

The next day after her explanation with her mother, Natasha waited the whole day for Bolkonsky, but he did not come. The next, third day the same thing happened. Pierre also did not come, and Natasha, not knowing that Prince Andrei had gone to his father, could not explain his absence.
Three weeks passed like this. Natasha did not want to go anywhere and, like a shadow, idle and sad, she walked from room to room, cried secretly from everyone in the evening and did not appear to her mother in the evenings. She was constantly blushing and irritated. It seemed to her that everyone knew about her disappointment, laughed and felt sorry for her. With all the strength of her inner grief, this vain grief intensified her misfortune.
One day she came to the countess, wanted to tell her something, and suddenly began to cry. Her tears were the tears of an offended child who himself does not know why he is being punished.
The Countess began to calm Natasha down. Natasha, who had been listening at first to her mother’s words, suddenly interrupted her:
- Stop it, mom, I don’t think, and I don’t want to think! So, I drove and stopped, and stopped...
Her voice trembled, she almost cried, but she recovered and calmly continued: “And I don’t want to get married at all.” And I'm afraid of him; I have now completely, completely calmed down...
The next day after this conversation, Natasha put on that old dress, which she was especially famous for the cheerfulness it brought in the morning, and in the morning she began her old way of life, from which she had fallen behind after the ball. After drinking tea, she went to the hall, which she especially loved for its strong resonance, and began to sing her solfeges (singing exercises). Having finished the first lesson, she stopped in the middle of the hall and repeated one musical phrase that she especially liked. She listened joyfully to the (as if unexpected for her) charm with which these shimmering sounds filled the entire emptiness of the hall and slowly froze, and she suddenly felt cheerful. “It’s good to think about it so much,” she said to herself and began to walk back and forth around the hall, not walking with simple steps on the ringing parquet floor, but at every step shifting from heel (she was wearing her new, favorite shoes) to toe, and just as joyfully as I listen to the sounds of my own voice, listening to this measured clatter of a heel and the creaking of a sock. Passing by the mirror, she looked into it. - "Here I am!" as if the expression on her face when she saw herself spoke. - “Well, that’s good. And I don’t need anyone.”
The footman wanted to enter to clean something in the hall, but she did not let him in, again closing the door behind him, and continued her walk. This morning she returned again to her favorite state of self-love and admiration for herself. - “What a charm this Natasha is!” she said again to herself in the words of some third, collective, male person. “She’s good, she has a voice, she’s young, and she doesn’t bother anyone, just leave her alone.” But no matter how much they left her alone, she could no longer be calm and she immediately felt it.
The entrance door opened in the hallway, and someone asked: “Are you at home?” and someone's steps were heard. Natasha looked in the mirror, but she did not see herself. She listened to sounds in the hall. When she saw herself, her face was pale. It was he. She knew this for sure, although she barely heard the sound of his voice from the closed doors.
Natasha, pale and frightened, ran into the living room.
- Mom, Bolkonsky has arrived! - she said. - Mom, this is terrible, this is unbearable! – I don’t want... to suffer! What should I do?…
Before the countess even had time to answer her, Prince Andrei entered the living room with an anxious and serious face. As soon as he saw Natasha, his face lit up. He kissed the hand of the countess and Natasha and sat down near the sofa.
“We haven’t had the pleasure for a long time...” the countess began, but Prince Andrei interrupted her, answering her question and obviously in a hurry to say what he needed.
“I wasn’t with you all this time because I was with my father: I needed to talk to him about a very important matter.” “I just returned last night,” he said, looking at Natasha. “I need to talk to you, Countess,” he added after a moment of silence.
The Countess, sighing heavily, lowered her eyes.
“I am at your service,” she said.
Natasha knew that she had to leave, but she could not do it: something was squeezing her throat, and she looked discourteously, directly, with open eyes at Prince Andrei.
"Now? This minute!... No, this can’t be!” she thought.
He looked at her again, and this look convinced her that she was not mistaken. “Yes, now, this very minute, her fate was being decided.”
“Come, Natasha, I’ll call you,” the countess said in a whisper.
Natasha looked at Prince Andrei and her mother with frightened, pleading eyes, and left.
“I came, Countess, to ask for your daughter’s hand in marriage,” said Prince Andrei. The countess's face flushed, but she said nothing.
“Your proposal...” the countess began sedately. “He was silent, looking into her eyes. – Your offer... (she was embarrassed) we are pleased, and... I accept your offer, I’m glad. And my husband... I hope... but it will depend on her...
“I’ll tell her when I have your consent... do you give it to me?” - said Prince Andrei.
“Yes,” said the countess and extended her hand to him and, with a mixed feeling of aloofness and tenderness, pressed her lips to his forehead as he leaned over her hand. She wanted to love him like a son; but she felt that he was a stranger and a terrible person for her. “I’m sure my husband will agree,” said the countess, “but your father...
“My father, to whom I communicated my plans, made it an indispensable condition of consent that the wedding should not be before a year. And this is what I wanted to tell you,” said Prince Andrei.
– It’s true that Natasha is still young, but for so long.
“It couldn’t be otherwise,” said Prince Andrei with a sigh.
“I will send it to you,” said the countess and left the room.
“Lord, have mercy on us,” she repeated, looking for her daughter. Sonya said that Natasha is in the bedroom. Natasha sat on her bed, pale, with dry eyes, looking at the icons and, quickly crossing herself, whispering something. Seeing her mother, she jumped up and rushed to her.
- What? Mom?... What?
- Go, go to him. “He asks for your hand,” the countess said coldly, as it seemed to Natasha... “Come... come,” the mother said with sadness and reproach after her running daughter, and sighed heavily.
Natasha did not remember how she entered the living room. Entering the door and seeing him, she stopped. “Has this stranger really become everything to me now?” she asked herself and instantly answered: “Yes, that’s it: he alone is now dearer to me than everything in the world.” Prince Andrei approached her, lowering his eyes.
“I loved you from the moment I saw you.” Can I hope?
He looked at her, and the serious passion in her expression struck him. Her face said: “Why ask? Why doubt something you can’t help but know? Why talk when you can’t express in words what you feel.”
She approached him and stopped. He took her hand and kissed it.
- Do you love me?
“Yes, yes,” Natasha said as if with annoyance, sighed loudly, and another time, more and more often, and began to sob.
- About what? What's wrong with you?
“Oh, I’m so happy,” she answered, smiled through her tears, leaned closer to him, thought for a second, as if asking herself if this was possible, and kissed him.
Prince Andrei held her hands, looked into her eyes, and did not find in his soul the same love for her. Something suddenly turned in his soul: there was no former poetic and mysterious charm of desire, but there was pity for her feminine and childish weakness, there was fear of her devotion and gullibility, a heavy and at the same time joyful consciousness of the duty that forever connected him with her. The real feeling, although it was not as light and poetic as the previous one, was more serious and stronger.

The Earth's atmosphere is heterogeneous: on different heights Different air densities and pressures are observed, temperature and gas composition changes. Based on the behavior of the ambient air temperature (i.e., the temperature increases or decreases with height), the following layers are distinguished in it: troposphere, stratosphere, mesosphere, thermosphere and exosphere. The boundaries between layers are called pauses: there are 4 of them, because the upper boundary of the exosphere is very blurred and often refers to near space.

WITH

The lowest atmospheric layer is the troposphere, the upper boundary of which is called the tropopause, depending on geographical latitude varies and ranges from 8 km. in the polar up to 20 km. in tropical latitudes. In middle or temperate latitudes, its upper limit lies at altitudes of 10-12 km. During the year, the upper limit of the troposphere experiences fluctuations depending on the influx of solar radiation. So, as a result of probing South Pole Earth, the US Meteorological Service has revealed that from March to August or September there is a steady cooling of the troposphere, as a result of which for a short period in August or September its boundary rises to 11.5 km. Then, in the period from September to December, it quickly decreases and reaches its lowest position - 7.5 km, after which its height remains virtually unchanged until March. Those. The troposphere reaches its greatest thickness in summer and its thinnest in winter.

It is worth noting that, in addition to seasonal ones, there are also daily fluctuations in the height of the tropopause. Also, its position is influenced by cyclones and anticyclones: in the first, it falls, because The pressure in them is lower than in the surrounding air, and secondly, it rises accordingly.

The troposphere contains up to 90% of the total mass of earth's air and 9/10 of all water vapor. Turbulence is highly developed here, especially in the near-surface and highest layers, clouds of all levels develop, cyclones and anticyclones form. And thanks to the accumulation of greenhouse gases ( carbon dioxide, methane, water vapor) reflected from the Earth's surface sun rays the greenhouse effect develops.

WITH greenhouse effect A decrease in air temperature in the troposphere is associated with altitude (since the heated Earth gives off more heat to the surface layers). The average vertical gradient is 0.65°/100 m (i.e., the air temperature decreases by 0.65° C for every 100 meters of rise). So, if the average annual air temperature at the surface of the Earth near the equator is +26°, then at the upper boundary it is -70°. The temperature in the tropopause region above the North Pole varies throughout the year from -45° in summer to -65° in winter.

With increasing altitude, air pressure also decreases, amounting to only 12-20% of the near-surface level at the upper boundary of the troposphere.

At the boundary of the troposphere and the overlying layer of the stratosphere lies a layer of the tropopause, 1-2 km thick. The lower boundaries of the tropopause are usually taken to be a layer of air in which the vertical gradient decreases to 0.2°/100 m versus 0.65°/100 m in the underlying regions of the troposphere.

Within the tropopause, air flows of a strictly defined direction are observed, called high-altitude jet streams or “jet streams”, formed under the influence of the rotation of the Earth around its axis and heating of the atmosphere with the participation of solar radiation. Currents are observed at the boundaries of zones with significant temperature differences. There are several centers of localization of these currents, for example, arctic, subtropical, subpolar and others. Knowledge of the localization of jet streams is very important for meteorology and aviation: the first uses streams for more accurate weather forecasting, the second for constructing aircraft flight routes, because At the boundaries of the flows, there are strong turbulent vortices, similar to small whirlpools, called “clear-sky turbulence” due to the absence of clouds at these altitudes.

Under the influence of high-altitude jet currents, breaks often form in the tropopause, and at times it disappears altogether, although it then forms anew. This is especially often observed in subtropical latitudes, which are dominated by a powerful subtropical high-altitude current. In addition, the difference in tropopause layers in ambient temperature leads to the formation of gaps. For example, a large gap exists between the warm and low polar tropopause and the high and cold tropopause of tropical latitudes. Recently, a layer of the tropopause of temperate latitudes has also emerged, which has discontinuities with the previous two layers: polar and tropical.

The second layer of the earth's atmosphere is the stratosphere.

Above the inversion region there is a layer of constant temperatures, which is called the stratopause and is the boundary between the stratosphere and mesosphere.

Its thickness reaches 15 km.

Unlike the troposphere, turbulent disturbances are rare in the stratosphere, but there are strong horizontal winds or jet streams blowing in narrow zones along the boundaries of temperate latitudes facing the poles. The position of these zones is not constant: they can shift, expand, or even disappear altogether.

Often jet streams penetrate into the upper layers of the troposphere, or, conversely, air masses from the troposphere penetrate into the lower layers of the stratosphere.

Such mixing of air masses is especially typical in areas of atmospheric fronts. There is little water vapor in the stratosphere. The air here is very dry, and therefore few clouds form. Only at altitudes of 20-25 km, being in high latitudes, can you notice very thin pearlescent clouds consisting of supercooled water droplets. During the day, these clouds are not visible, but with the onset of darkness they seem to glow due to the illumination of them by the Sun, which has already set below the horizon. At the same altitudes (20-25 km) in the lower stratosphere there is the so-called ozone layer - the area with the highest content of ozone, which is formed under the influence of ultraviolet solar radiation (you can find out more about this process on the page). The ozone layer or ozonosphere is of extreme importance for maintaining the life of all organisms living on land, absorbing deadly ultraviolet rays with a wavelength of up to 290 nm. It is for this reason that living organisms do not live above the ozone layer; it is the upper limit of the distribution of life on Earth.

Ozone also changes

Here, within the mesopause, lies the lower boundary of the region of active absorption of X-ray and short-wave ultraviolet radiation from the Sun. This energy process is called radiant heat transfer. As a result, the gas is heated and ionized, which causes the atmosphere to glow.

At altitudes of 75-90 km at the upper boundaries of the mesosphere, special clouds were noted, occupying vast areas in the polar regions of the planet. These clouds are called noctilucent because of their glow at dusk, which is caused by the reflection of sunlight from the ice crystals of which these clouds are composed.

Air pressure within the mesopause is 200 times less than that of earth's surface. This suggests that almost all the air in the atmosphere is concentrated in its 3 lower layers: the troposphere, stratosphere and mesosphere. The overlying layers, the thermosphere and exosphere, account for only 0.05% of the mass of the entire atmosphere.

The thermosphere lies at altitudes from 90 to 800 km above the Earth's surface.

The thermosphere is characterized by a continuous increase in air temperature to altitudes of 200-300 km, where it can reach 2500°C. The temperature rises due to the absorption of X-rays and short-wavelength ultraviolet radiation from the Sun by gas molecules. Above 300 km above sea level, the temperature increase stops.

Simultaneously with the increase in temperature, the pressure and, consequently, the density of the surrounding air decreases. So if at the lower boundaries of the thermosphere the density is 1.8 × 10 -8 g/cm 3, then at the upper boundaries it is already 1.8 × 10 -15 g/cm 3, which approximately corresponds to 10 million - 1 billion particles per 1 cm 3.

All characteristics of the thermosphere, such as the composition of air, its temperature, density, are subject to strong fluctuations: depending on the geographical location, season of the year and time of day. Even the location of the upper boundary of the thermosphere changes.

The uppermost layer of the atmosphere is called the exosphere or scattering layer. Its lower limit is constantly changing within very wide limits; The average height is taken to be 690-800 km. It is installed where the probability of intermolecular or interatomic collisions can be neglected, i.e. the average distance that a chaotically moving molecule will cover before colliding with another similar molecule (the so-called free path) will be so great that in fact the molecules will not collide with a probability close to zero. The layer where the described phenomenon occurs is called thermal pause.

The upper boundary of the exosphere lies at altitudes of 2-3 thousand km. It is greatly blurred and gradually turns into a near-space vacuum. Sometimes, for this reason, the exosphere is considered part of outer space, and its upper limit is taken to be a height of 190 thousand km, at which the influence of solar radiation pressure on the speed of hydrogen atoms exceeds the gravitational attraction of the Earth. This is the so-called the earth's crown, consisting of hydrogen atoms. The density of the earth's corona is very small: only 1000 particles per cubic centimeter, but this number is more than 10 times higher than the concentration of particles in interplanetary space.

Due to the extreme rarefaction of the air in the exosphere, particles move around the Earth in elliptical orbits without colliding with each other. Some of them, moving along open or hyperbolic trajectories at cosmic speeds (hydrogen and helium atoms), leave the atmosphere and go into outer space, which is why the exosphere is called the scattering sphere.

The structure of the Earth's atmosphere

The atmosphere is the gaseous shell of the Earth with the aerosol particles it contains, moving together with the Earth in space as a single whole and at the same time taking part in the rotation of the Earth. Most of our life takes place at the bottom of the atmosphere.

Almost all of our planets have their own atmospheres. solar system, but only the earth's atmosphere is capable of supporting life.

When our planet formed 4.5 billion years ago, it was apparently devoid of an atmosphere. The atmosphere was formed as a result of volcanic emissions of water vapor mixed with carbon dioxide, nitrogen and other chemical substances from the depths of the young planet. But the atmosphere can contain a limited amount of moisture, so its excess as a result of condensation gave rise to the oceans. But then the atmosphere was devoid of oxygen. The first living organisms that originated and developed in the ocean, as a result of the photosynthesis reaction (H 2 O + CO 2 = CH 2 O + O 2), began to release small portions of oxygen, which began to enter the atmosphere.

The formation of oxygen in the Earth's atmosphere led to the formation of the ozone layer at altitudes of approximately 8 – 30 km. And, thus, our planet has acquired protection from the harmful effects of ultraviolet study. This circumstance served as an impetus for the further evolution of life forms on Earth, because As a result of increased photosynthesis, the amount of oxygen in the atmosphere began to grow rapidly, which contributed to the formation and maintenance of life forms, including on land.

Today our atmosphere consists of 78.1% nitrogen, 21% oxygen, 0.9% argon, and 0.04% carbon dioxide. Very small fractions compared to the main gases are neon, helium, methane, and krypton.

The gas particles contained in the atmosphere are affected by the force of gravity of the Earth. And, given that air is compressible, its density gradually decreases with height, passing into outer space without a clear boundary. Half of the total mass of the earth's atmosphere is concentrated in the lower 5 km, three quarters in the lower 10 km, nine tenths in the lower 20 km. 99% of the mass of the Earth's atmosphere is concentrated below an altitude of 30 km, which is only 0.5% of the equatorial radius of our planet.

At sea level, the number of atoms and molecules per cubic centimeter of air is about 2 * 10 19, at an altitude of 600 km only 2 * 10 7. At sea level, an atom or molecule travels approximately 7 * 10 -6 cm before colliding with another particle. At an altitude of 600 km this distance is about 10 km. And at sea level, about 7 * 10 9 such collisions occur every second, at an altitude of 600 km - only about one per minute!

But not only pressure changes with altitude. The temperature also changes. For example, at the foot of a high mountain it can be quite hot, while the top of the mountain is covered with snow and the temperature there is at the same time below zero. And if you take a plane to an altitude of about 10-11 km, you can hear a message that it is -50 degrees outside, while at the surface of the earth it is 60-70 degrees warmer...

Initially, scientists assumed that the temperature decreases with height until it reaches absolute zero (-273.16°C). But that's not true.

The Earth's atmosphere consists of four layers: troposphere, stratosphere, mesosphere, ionosphere (thermosphere). This division into layers was also adopted based on data on temperature changes with height. The lowest layer, where air temperature decreases with height, is called the troposphere. The layer above the troposphere, where the temperature drop stops, is replaced by isotherm, and finally the temperature begins to rise, is called the stratosphere. The layer above the stratosphere in which the temperature rapidly drops again is the mesosphere. And finally, the layer where the temperature begins to rise again is called the ionosphere or thermosphere.

The troposphere extends on average to the lower 12 km. This is where our weather is formed. The highest clouds (cirrus) form in the uppermost layers of the troposphere. The temperature in the troposphere decreases adiabatically with height, i.e. The temperature change occurs due to the decrease in pressure with height. The temperature profile of the troposphere is largely determined by the amount of water reaching the Earth's surface. solar radiation. As a result of the heating of the Earth's surface by the Sun, convective and turbulent flows are formed, directed upward, which form the weather. It is worth noting that the influence of the underlying surface on the lower layers of the troposphere extends to a height of approximately 1.5 km. Of course, excluding mountainous areas.

The upper boundary of the troposphere is the tropopause - an isothermal layer. Remember characteristic appearance thunderclouds whose top is a “burst” of cirrus clouds called an “anvil.” This “anvil” just “spreads” under the tropopause, because due to isotherm, the ascending air currents are significantly weakened, and the cloud stops developing vertically. But in special, rare cases, the tops of cumulonimbus clouds can invade the lower layers of the stratosphere, breaking the tropopause.

The height of the tropopause depends on the geographic latitude. Thus, at the equator it is located at an altitude of approximately 16 km, and its temperature is about –80°C. At the poles, the tropopause is located lower, at approximately 8 km altitude. In summer the temperature here is –40°C, and –60°C in winter. Thus, despite higher temperatures at the Earth's surface, the tropical tropopause is much colder than at the poles.