The atmosphere is a layer of the earth. Layers of the atmosphere - troposphere, stratosphere, mesosphere, thermosphere and exosphere
The atmosphere began to form along with the formation of the Earth. In the course of the evolution of the planet and as its parameters approached modern values, there were fundamentally qualitative changes in its chemical composition and physical properties. According to the evolutionary model, at an early stage, the Earth was in a molten state and formed as a solid body about 4.5 billion years ago. This milestone is taken as the beginning of the geological chronology. Since that time, the slow evolution of the atmosphere began. Some geological processes (for example, outpourings of lava during volcanic eruptions) were accompanied by the release of gases from the bowels of the Earth. They included nitrogen, ammonia, methane, water vapor, CO2 oxide and CO2 carbon dioxide. Under the influence of solar ultraviolet radiation, water vapor decomposed into hydrogen and oxygen, but the released oxygen reacted with carbon monoxide, forming carbon dioxide. Ammonia decomposed into nitrogen and hydrogen. Hydrogen in the process of diffusion rose up and left the atmosphere, while heavier nitrogen could not escape and gradually accumulated, becoming the main component, although some of it was bound into molecules as a result of chemical reactions ( cm. CHEMISTRY OF THE ATMOSPHERE). Under the influence of ultraviolet rays and electrical discharges, a mixture of gases that were present in the original atmosphere of the Earth entered into chemical reactions, which resulted in the formation of organic substances, in particular amino acids. With the advent of primitive plants, the process of photosynthesis began, accompanied by the release of oxygen. This gas, especially after diffusion into the upper atmosphere, began to protect its lower layers and the Earth's surface from life-threatening ultraviolet and X-ray radiation. According to theoretical estimates, the oxygen content, which is 25,000 times less than now, could already lead to the formation of an ozone layer with only half as much as it is now. However, this is already enough to provide a very significant protection of organisms from the damaging effects of ultraviolet rays.
It is likely that the primary atmosphere contained a lot of carbon dioxide. It was consumed during photosynthesis, and its concentration must have decreased as the plant world evolved, and also due to absorption during some geological processes. Because the Greenhouse effect associated with the presence of carbon dioxide in the atmosphere, fluctuations in its concentration are one of the important reasons for such large-scale climate change in the history of the earth ice ages.
Most of the helium present in the modern atmosphere is a product of radioactive decay uranium, thorium and radium. These radioactive elements emit a-particles, which are the nuclei of helium atoms. Since no electric charge is formed and does not disappear during radioactive decay, with the formation of each a-particle, two electrons appear, which, recombining with a-particles, form neutral helium atoms. Radioactive elements are contained in minerals scattered in the thickness rocks, therefore, a significant part of the helium formed as a result of radioactive decay is stored in them, escaping very slowly into the atmosphere. A certain amount of helium rises up into the exosphere due to diffusion, but due to the constant influx from the earth's surface, the volume of this gas in the atmosphere remains almost unchanged. Based on the spectral analysis of starlight and the study of meteorites, it is possible to estimate the relative abundance of various chemical elements in the Universe. The concentration of neon in space is about ten billion times higher than on Earth, krypton - ten million times, and xenon - a million times. It follows from this that the concentration of these inert gases, apparently originally present in the Earth's atmosphere and not replenished in the course of chemical reactions, greatly decreased, probably even at the stage of the Earth's loss of its primary atmosphere. An exception is the inert gas argon, since it is still formed in the form of the 40 Ar isotope in the process of radioactive decay of the potassium isotope.
Barometric pressure distribution.
The total weight of atmospheric gases is approximately 4.5 10 15 tons. Thus, the "weight" of the atmosphere per unit area, or atmospheric pressure, is approximately 11 t / m 2 = 1.1 kg / cm 2 at sea level. Pressure equal to P 0 \u003d 1033.23 g / cm 2 \u003d 1013.250 mbar \u003d 760 mm Hg. Art. = 1 atm, taken as the standard mean atmospheric pressure. For an atmosphere in hydrostatic equilibrium, we have: d P= -rgd h, which means that on the interval of heights from h before h+d h occurs equality between atmospheric pressure change d P and the weight of the corresponding element of the atmosphere with unit area, density r and thickness d h. As a ratio between pressure R and temperature T the equation of state of an ideal gas with density r, which is quite applicable for the earth's atmosphere, is used: P= r R T/m, where m is molecular mass, and R = 8.3 J/(K mol) is the universal gas constant. Then dlog P= – (m g/RT)d h= -bd h= – d h/H, where the pressure gradient is on a logarithmic scale. The reciprocal of H is to be called the scale of the height of the atmosphere.
When integrating this equation for an isothermal atmosphere ( T= const) or for its part, where such an approximation is acceptable, the barometric law of pressure distribution with height is obtained: P = P 0 exp(- h/H 0), where the height reading h produced from ocean level, where the standard mean pressure is P 0 . Expression H 0=R T/ mg, is called the height scale, which characterizes the extent of the atmosphere, provided that the temperature in it is the same everywhere (isothermal atmosphere). If the atmosphere is not isothermal, then it is necessary to integrate taking into account the change in temperature with height, and the parameter H- some local characteristic of the layers of the atmosphere, depending on their temperature and the properties of the medium.
Standard atmosphere.
Model (table of values of the main parameters) corresponding to the standard pressure at the base of the atmosphere R 0 and chemical composition is called the standard atmosphere. More precisely, this is a conditional model of the atmosphere, for which the average values for the latitude 45° 32° 33І are given for temperature, pressure, density, viscosity, and other air characteristics at altitudes from 2 km below sea level to the outer boundary of the earth's atmosphere. The parameters of the middle atmosphere at all altitudes were calculated using the ideal gas equation of state and the barometric law assuming that at sea level the pressure is 1013.25 hPa (760 mmHg) and the temperature is 288.15 K (15.0°C). According to the nature of the vertical temperature distribution, the average atmosphere consists of several layers, in each of which the temperature is approximated by a linear function of height. In the lowest of the layers - the troposphere (h Ј 11 km), the temperature drops by 6.5 ° C with each kilometer of ascent. At high altitudes, the value and sign of the vertical temperature gradient change from layer to layer. Above 790 km, the temperature is about 1000 K and practically does not change with height.
The standard atmosphere is a periodically updated, legalized standard, issued in the form of tables.
Table 1. STANDARD EARTH ATMOSPHERE MODEL. The table shows: h- height from sea level, R- pressure, T– temperature, r – density, N is the number of molecules or atoms per unit volume, H- height scale, l is the length of the free path. Pressure and temperature at an altitude of 80–250 km, obtained from rocket data, have lower values. Extrapolated values for heights greater than 250 km are not very accurate. | ||||||
h(km) | P(mbar) | T(°C) | r (g / cm 3) | N(cm -3) | H(km) | l(cm) |
0 | 1013 | 288 | 1.22 10 -3 | 2.55 10 19 | 8,4 | 7.4 10 -6 |
1 | 899 | 281 | 1.11 10 -3 | 2.31 10 19 | 8.1 10 -6 | |
2 | 795 | 275 | 1.01 10 -3 | 2.10 10 19 | 8.9 10 -6 | |
3 | 701 | 268 | 9.1 10 -4 | 1.89 10 19 | 9.9 10 -6 | |
4 | 616 | 262 | 8.2 10 -4 | 1.70 10 19 | 1.1 10 -5 | |
5 | 540 | 255 | 7.4 10 -4 | 1.53 10 19 | 7,7 | 1.2 10 -5 |
6 | 472 | 249 | 6.6 10 -4 | 1.37 10 19 | 1.4 10 -5 | |
8 | 356 | 236 | 5.2 10 -4 | 1.09 10 19 | 1.7 10 -5 | |
10 | 264 | 223 | 4.1 10 -4 | 8.6 10 18 | 6,6 | 2.2 10 -5 |
15 | 121 | 214 | 1.93 10 -4 | 4.0 10 18 | 4.6 10 -5 | |
20 | 56 | 214 | 8.9 10 -5 | 1.85 10 18 | 6,3 | 1.0 10 -4 |
30 | 12 | 225 | 1.9 10 -5 | 3.9 10 17 | 6,7 | 4.8 10 -4 |
40 | 2,9 | 268 | 3.9 10 -6 | 7.6 10 16 | 7,9 | 2.4 10 -3 |
50 | 0,97 | 276 | 1.15 10 -6 | 2.4 10 16 | 8,1 | 8.5 10 -3 |
60 | 0,28 | 260 | 3.9 10 -7 | 7.7 10 15 | 7,6 | 0,025 |
70 | 0,08 | 219 | 1.1 10 -7 | 2.5 10 15 | 6,5 | 0,09 |
80 | 0,014 | 205 | 2.7 10 -8 | 5.0 10 14 | 6,1 | 0,41 |
90 | 2.8 10 -3 | 210 | 5.0 10 -9 | 9 10 13 | 6,5 | 2,1 |
100 | 5.8 10 -4 | 230 | 8.8 10 -10 | 1.8 10 13 | 7,4 | 9 |
110 | 1.7 10 -4 | 260 | 2.1 10 –10 | 5.4 10 12 | 8,5 | 40 |
120 | 6 10 -5 | 300 | 5.6 10 -11 | 1.8 10 12 | 10,0 | 130 |
150 | 5 10 -6 | 450 | 3.2 10 -12 | 9 10 10 | 15 | 1.8 10 3 |
200 | 5 10 -7 | 700 | 1.6 10 -13 | 5 10 9 | 25 | 3 10 4 |
250 | 9 10 -8 | 800 | 3 10 -14 | 8 10 8 | 40 | 3 10 5 |
300 | 4 10 -8 | 900 | 8 10 -15 | 3 10 8 | 50 | |
400 | 8 10 -9 | 1000 | 1 10 –15 | 5 10 7 | 60 | |
500 | 2 10 -9 | 1000 | 2 10 -16 | 1 10 7 | 70 | |
700 | 2 10 –10 | 1000 | 2 10 -17 | 1 10 6 | 80 | |
1000 | 1 10 –11 | 1000 | 1 10 -18 | 1 10 5 | 80 |
Troposphere.
The lowest and densest layer of the atmosphere, in which the temperature decreases rapidly with height, is called the troposphere. It contains up to 80% of the total mass of the atmosphere and extends in polar and middle latitudes up to heights of 8–10 km, and in the tropics up to 16–18 km. Almost all weather-forming processes develop here, heat and moisture exchange occurs between the Earth and its atmosphere, clouds form, various meteorological phenomena occur, fogs and precipitation occur. These layers of the earth's atmosphere are in convective equilibrium and, due to active mixing, have a uniform chemical composition, mainly from molecular nitrogen (78%) and oxygen (21%). The vast majority of natural and man-made aerosol and gas air pollutants are concentrated in the troposphere. The dynamics of the lower part of the troposphere up to 2 km thick strongly depends on the properties of the underlying surface of the Earth, which determines the horizontal and vertical movements of air (winds) due to the transfer of heat from a warmer land through the IR radiation of the earth's surface, which is absorbed in the troposphere, mainly by vapor water and carbon dioxide (greenhouse effect). The temperature distribution with height is established as a result of turbulent and convective mixing. On average, it corresponds to a drop in temperature with height of about 6.5 K/km.
The wind speed in the surface boundary layer first increases rapidly with height, and higher it continues to increase by 2–3 km/s per kilometer. Sometimes in the troposphere there are narrow planetary streams (with a speed of more than 30 km / s), western ones in middle latitudes, and eastern ones near the equator. They are called jet streams.
tropopause.
At the upper boundary of the troposphere (tropopause), the temperature reaches its minimum value for the lower atmosphere. This is the transition layer between the troposphere and the stratosphere above it. The thickness of the tropopause is from hundreds of meters to 1.5–2 km, and the temperature and altitude, respectively, range from 190 to 220 K and from 8 to 18 km, depending on the geographic latitude and season. In temperate and high latitudes, in winter it is 1–2 km lower than in summer and 8–15 K warmer. In the tropics, seasonal changes are much less (altitude 16–18 km, temperature 180–200 K). Above jet streams possible rupture of the tropopause.
Water in the Earth's atmosphere.
The most important feature of the Earth's atmosphere is the presence of a significant amount of water vapor and water in droplet form, which is most easily observed in the form of clouds and cloud structures. The degree of cloud coverage of the sky (at a certain moment or on average over a certain period of time), expressed on a 10-point scale or as a percentage, is called cloudiness. The shape of the clouds is determined by the international classification. On average, clouds cover about half of the globe. Cloudiness is an important factor characterizing weather and climate. In winter and at night, cloudiness prevents a decrease in the temperature of the earth's surface and the surface layer of air, in summer and during the day it weakens the heating of the earth's surface by the sun's rays, softening the climate inside the continents.
Clouds.
Clouds are accumulations of water droplets suspended in the atmosphere (water clouds), ice crystals (ice clouds), or both (mixed clouds). As drops and crystals become larger, they fall out of the clouds in the form of precipitation. Clouds form mainly in the troposphere. They result from the condensation of water vapor contained in the air. The diameter of cloud drops is on the order of several microns. Content liquid water in the clouds - from fractions to several grams per m 3. Clouds are distinguished by height: According to the international classification, there are 10 genera of clouds: cirrus, cirrocumulus, cirrostratus, altocumulus, altostratus, stratonimbus, stratus, stratocumulus, cumulonimbus, cumulus.
Mother-of-pearl clouds are also observed in the stratosphere, and noctilucent clouds in the mesosphere.
Cirrus clouds - transparent clouds in the form of thin white threads or veils with a silky sheen, not giving a shadow. Cirrus clouds are made up of ice crystals and form in the upper troposphere at very low temperatures. Some types of cirrus clouds serve as harbingers of weather changes.
Cirrocumulus clouds are ridges or layers of thin white clouds in the upper troposphere. Cirrocumulus clouds are built from small elements that look like flakes, ripples, small balls without shadows and consist mainly of ice crystals.
Cirrostratus clouds - a whitish translucent veil in the upper troposphere, usually fibrous, sometimes blurry, consisting of small needle or columnar ice crystals.
Altocumulus clouds are white, gray or white-gray clouds of the lower and middle layers of the troposphere. Altocumulus clouds look like layers and ridges, as if built from plates lying one above the other, rounded masses, shafts, flakes. Altocumulus clouds form during intense convective activity and usually consist of supercooled water droplets.
Altostratus clouds are grayish or bluish clouds of a fibrous or uniform structure. Altostratus clouds are observed in the middle troposphere, extending several kilometers in height and sometimes thousands of kilometers in a horizontal direction. Usually, altostratus clouds are part of frontal cloud systems associated with ascending movements of air masses.
Nimbostratus clouds - a low (from 2 km and above) amorphous layer of clouds of a uniform gray color, giving rise to overcast rain or snow. Nimbostratus clouds - highly developed vertically (up to several km) and horizontally (several thousand km), consist of supercooled water drops mixed with snowflakes, usually associated with atmospheric fronts.
Stratus clouds - clouds of the lower tier in the form of a homogeneous layer without definite outlines, gray in color. Height of stratus above earth's surface is 0.5–2 km. Occasional drizzle falls from stratus clouds.
Cumulus clouds are dense, bright white clouds during the day with significant vertical development (up to 5 km or more). The upper parts of cumulus clouds look like domes or towers with rounded outlines. Cumulus clouds usually form as convection clouds in cold air masses.
Stratocumulus clouds - low (below 2 km) clouds in the form of gray or white non-fibrous layers or ridges of round large blocks. The vertical thickness of stratocumulus clouds is small. Occasionally, stratocumulus clouds give light precipitation.
Cumulonimbus clouds are powerful and dense clouds with a strong vertical development (up to a height of 14 km), giving heavy rainfall with thunderstorms, hail, squalls. Cumulonimbus clouds develop from powerful cumulus clouds, differing from them in the upper part, consisting of ice crystals.
Stratosphere.
Through the tropopause, on average at altitudes from 12 to 50 km, the troposphere passes into the stratosphere. In the lower part, for about 10 km, i.e. up to heights of about 20 km, it is isothermal (temperature about 220 K). Then it increases with altitude, reaching a maximum of about 270 K at an altitude of 50–55 km. Here is the boundary between the stratosphere and the overlying mesosphere, called the stratopause. .
There is much less water vapor in the stratosphere. Nevertheless, thin translucent mother-of-pearl clouds are occasionally observed, occasionally appearing in the stratosphere at a height of 20–30 km. Mother-of-pearl clouds are visible in the dark sky after sunset and before sunrise. In shape, mother-of-pearl clouds resemble cirrus and cirrocumulus clouds.
Middle atmosphere (mesosphere).
At an altitude of about 50 km, the mesosphere begins with the peak of a wide temperature maximum. . The reason for the increase in temperature in the region of this maximum is an exothermic (i.e., accompanied by the release of heat) photochemical reaction of ozone decomposition: O 3 + hv® O 2 + O. Ozone arises as a result of the photochemical decomposition of molecular oxygen O 2
About 2+ hv® O + O and the subsequent reaction of a triple collision of an atom and an oxygen molecule with some third molecule M.
O + O 2 + M ® O 3 + M
Ozone greedily absorbs ultraviolet radiation in the region from 2000 to 3000Å, and this radiation heats up the atmosphere. Ozone, located in the upper atmosphere, serves as a kind of shield that protects us from the action of ultraviolet radiation from the Sun. Without this shield, the development of life on Earth in its modern forms would hardly be possible.
In general, throughout the mesosphere, the temperature of the atmosphere decreases to its minimum value of about 180 K at the upper boundary of the mesosphere (called the mesopause, height is about 80 km). In the vicinity of the mesopause, at altitudes of 70–90 km, a very thin layer of ice crystals and particles of volcanic and meteorite dust can appear, observed in the form of a beautiful spectacle of noctilucent clouds. shortly after sunset.
In the mesosphere, for the most part, small solid meteorite particles that fall on the Earth are burned, causing the phenomenon of meteors.
Meteors, meteorites and fireballs.
Flares and other phenomena in the upper atmosphere of the Earth caused by the intrusion into it at a speed of 11 km / s and above solid cosmic particles or bodies are called meteoroids. There is an observed bright meteor trail; the most powerful phenomena, often accompanied by the fall of meteorites, are called fireballs; meteors are associated with meteor showers.
meteor shower:
1) the phenomenon of multiple meteor falls over several hours or days from one radiant.
2) a swarm of meteoroids moving in one orbit around the Sun.
The systematic appearance of meteors in a certain region of the sky and on certain days of the year, caused by the intersection of the Earth's orbit with a common orbit of many meteorite bodies moving at approximately the same and equally directed speeds, due to which their paths in the sky seem to come out of one common point (radiant) . They are named after the constellation where the radiant is located.
Meteor showers make a deep impression with their lighting effects, but individual meteors are rarely seen. Far more numerous are invisible meteors, too small to be seen at the moment they are swallowed up by the atmosphere. Some of the smallest meteors probably do not heat up at all, but are only captured by the atmosphere. These small particles ranging in size from a few millimeters to ten-thousandths of a millimeter are called micrometeorites. The amount of meteoric matter entering the atmosphere every day is from 100 to 10,000 tons, with most of this matter being micrometeorites.
Since meteoric matter partially burns up in the atmosphere, its gas composition is replenished with traces of various chemical elements. For example, stone meteors bring lithium into the atmosphere. The combustion of metallic meteors leads to the formation of tiny spherical iron, iron-nickel and other droplets that pass through the atmosphere and are deposited on the earth's surface. They can be found in Greenland and Antarctica, where ice sheets remain almost unchanged for years. Oceanologists find them in bottom ocean sediments.
Most of the meteor particles entering the atmosphere are deposited within approximately 30 days. Some scholars believe that this cosmic dust plays important role in the formation of such atmospheric phenomena as rain, since it serves as the nuclei of condensation of water vapor. Therefore, it is assumed that precipitation is statistically associated with large meteor showers. However, some experts believe that since the total input of meteoric matter is many tens of times greater than even with the largest meteor shower, the change in the total amount of this material that occurs as a result of one such shower can be neglected.
However, there is no doubt that the largest micrometeorites and visible meteorites leave long traces of ionization in the high layers of the atmosphere, mainly in the ionosphere. Such traces can be used for long-distance radio communications, as they reflect high-frequency radio waves.
The energy of meteors entering the atmosphere is spent mainly, and perhaps completely, on its heating. This is one of the minor components of the heat balance of the atmosphere.
A meteorite is a solid body of natural origin that fell to the surface of the Earth from space. Usually distinguish stone, iron-stone and iron meteorites. The latter are mainly composed of iron and nickel. Among the found meteorites, most have a weight of several grams to several kilograms. The largest of those found, the Goba iron meteorite weighs about 60 tons and still lies in the same place where it was discovered, in South Africa. Most meteorites are fragments of asteroids, but some meteorites may have come to Earth from the Moon and even from Mars.
A fireball is a very bright meteor, sometimes observed even during the day, often leaving behind a smoky trail and accompanied by sound phenomena; often ends with the fall of meteorites.
Thermosphere.
Above the temperature minimum of the mesopause, the thermosphere begins, in which the temperature, at first slowly, and then quickly, begins to rise again. The reason is the absorption of ultraviolet, solar radiation at altitudes of 150–300 km, due to the ionization of atomic oxygen: O + hv® O + + e.
In the thermosphere, the temperature continuously rises to a height of about 400 km, where it reaches a maximum during the daytime solar activity 1800 K. In the epoch of minimum, this limiting temperature can be less than 1000 K. Above 400 km, the atmosphere passes into an isothermal exosphere. The critical level (the base of the exosphere) is located at an altitude of about 500 km.
Auroras and many orbits artificial satellites, as well as noctilucent clouds - all these phenomena occur in the mesosphere and thermosphere.
Polar Lights.
At high latitudes, auroras are observed during magnetic field disturbances. They may last for several minutes, but are often visible for several hours. Auroras vary greatly in shape, color and intensity, all of which sometimes change very rapidly over time. The aurora spectrum consists of emission lines and bands. Some of the emissions from the night sky are enhanced in the aurora spectrum, primarily the green and red lines of l 5577 Å and l 6300 Å of oxygen. It happens that one of these lines is many times more intense than the other, and this determines the visible color of the radiance: green or red. Disturbances in the magnetic field are also accompanied by disruptions in radio communications in the polar regions. The disruption is caused by changes in the ionosphere, which means that during magnetic storms a powerful source of ionization operates. It has been established that strong magnetic storms occur when there are large groups of spots near the center of the solar disk. Observations have shown that storms are associated not with the spots themselves, but with solar flares that appear during the development of a group of spots.
The auroras are a range of light of varying intensity with rapid movements observed in the high latitude regions of the Earth. The visual aurora contains green (5577Å) and red (6300/6364Å) emission lines of atomic oxygen and N 2 molecular bands, which are excited by energetic particles of solar and magnetospheric origin. These emissions are usually displayed at an altitude of about 100 km and above. The term optical aurora is used to refer to the visual auroras and their infrared to ultraviolet emission spectrum. The radiation energy in the infrared part of the spectrum significantly exceeds the energy of the visible region. When auroras appeared, emissions were observed in the ULF range (
The actual forms of auroras are difficult to classify; The following terms are most commonly used:
1. Calm uniform arcs or stripes. The arc usually extends for ~1000 km in the direction of the geomagnetic parallel (toward the Sun in the polar regions) and has a width from one to several tens of kilometers. A strip is a generalization of the concept of an arc, it usually does not have a regular arcuate shape, but bends in the form of an S or in the form of spirals. Arcs and bands are located at altitudes of 100–150 km.
2. Rays of aurora . This term refers to an auroral structure stretched along magnetic field lines with a vertical extension from several tens to several hundreds of kilometers. The length of the rays along the horizontal is small, from several tens of meters to several kilometers. Rays are usually observed in arcs or as separate structures.
3. Stains or surfaces . These are isolated areas of glow that do not have a specific shape. Individual spots may be related.
4. Veil. An unusual form of aurora, which is a uniform glow that covers large areas of the sky.
According to the structure, the auroras are divided into homogeneous, polish and radiant. Are used various terms; pulsating arc, pulsating surface, diffuse surface, radiant stripe, drapery, etc. There is a classification of auroras according to their color. According to this classification, auroras of the type A. The upper part or completely are red (6300–6364 Å). They usually appear at altitudes of 300–400 km during high geomagnetic activity.
Aurora type IN are colored red in the lower part and are associated with the luminescence of the bands of the first positive N 2 system and the first negative O 2 system. Such forms of aurora appear during the most active phases of auroras.
Zones auroras – these are zones of maximum frequency of occurrence of auroras at night, according to observers at a fixed point on the Earth's surface. The zones are located at 67° north and south latitude, and their width is about 6°. The maximum occurrence of auroras, corresponding to a given moment of geomagnetic local time, occurs in oval-like belts (aurora oval), which are located asymmetrically around the north and south geomagnetic poles. The aurora oval is fixed in latitude-time coordinates, and the auroral zone is the locus of points in the midnight region of the oval in latitude-longitude coordinates. The oval belt is located approximately 23° from the geomagnetic pole in the night sector and 15° in the day sector.
Auroral oval and aurora zones. The location of the aurora oval depends on geomagnetic activity. The oval becomes wider at high geomagnetic activity. Aurora zones or aurora oval boundaries are better represented by L 6.4 than by dipole coordinates. The geomagnetic field lines at the boundary of the daytime sector of the aurora oval coincide with magnetopause. There is a change in the position of the aurora oval depending on the angle between the geomagnetic axis and the Earth-Sun direction. The auroral oval is also determined on the basis of data on the precipitation of particles (electrons and protons) of certain energies. Its position can be independently determined from data on caspakh on the dayside and in the magnetotail.
The daily variation in the frequency of occurrence of auroras in the aurora zone has a maximum at geomagnetic midnight and a minimum at geomagnetic noon. On the near-equatorial side of the oval, the frequency of occurrence of auroras sharply decreases, but the shape of diurnal variations is retained. On the polar side of the oval, the frequency of occurrence of auroras decreases gradually and is characterized by complex diurnal changes.
Intensity of auroras.
Aurora Intensity determined by measuring the apparent luminance surface. Brightness surface I auroras in a certain direction is determined by the total emission 4p I photon/(cm 2 s). Since this value is not the true surface brightness, but represents the emission from the column, the unit photon/(cm 2 column s) is usually used in the study of auroras. The usual unit for measuring total emission is Rayleigh (Rl) equal to 10 6 photon / (cm 2 column s). A more practical unit of aurora intensity is determined from the emissions of a single line or band. For example, the intensity of the auroras is determined by the international brightness coefficients (ICF) according to the green line intensity data (5577 Å); 1 kRl = I MKH, 10 kRl = II MKH, 100 kRl = III MKH, 1000 kRl = IV MKH (maximum aurora intensity). This classification cannot be used for red auroras. One of the discoveries of the epoch (1957–1958) was the establishment of the spatial and temporal distribution of auroras in the form of an oval displaced relative to the magnetic pole. From simple ideas about the circular shape of the distribution of auroras relative to the magnetic pole, the transition to modern physics of the magnetosphere was completed. The honor of the discovery belongs to O. Khorosheva, and G. Starkov, J. Feldshtein, S-I. The aurora oval is the region of the most intense impact of the solar wind on the Earth's upper atmosphere. The intensity of auroras is greatest in the oval, and its dynamics are continuously monitored by satellites.
Stable auroral red arcs.
Steady auroral red arc, otherwise called the mid-latitude red arc or M-arc, is a subvisual (below the sensitivity limit of the eye) wide arc, stretched from east to west for thousands of kilometers and encircling, possibly, the entire Earth. The latitudinal extent of the arc is 600 km. The emission from the stable auroral red arc is almost monochromatic in the red lines l 6300 Å and l 6364 Å. Recently, weak emission lines l 5577 Å (OI) and l 4278 Å (N + 2) have also been reported. Persistent red arcs are classified as auroras, but they appear at much higher altitudes. The lower limit is located at an altitude of 300 km, the upper limit is about 700 km. The intensity of the quiet auroral red arc in the l 6300 Å emission ranges from 1 to 10 kRl (a typical value is 6 kRl). The sensitivity threshold of the eye at this wavelength is about 10 kR, so arcs are rarely observed visually. However, observations have shown that their brightness is >50 kR on 10% of nights. The usual lifetime of the arcs is about one day, and they rarely appear in the following days. Radio waves from satellites or radio sources crossing stable auroral red arcs are subject to scintillations, indicating the existence of electron density inhomogeneities. The theoretical explanation of the red arcs is that the heated electrons of the region F ionospheres cause an increase in oxygen atoms. Satellite observations show an increase in electron temperature along field lines geomagnetic field, which cross stable auroral red arcs. The intensity of these arcs correlates positively with geomagnetic activity (storms), and the frequency of occurrence of arcs correlates positively with solar sunspot activity.
Changing aurora.
Some forms of auroras experience quasi-periodic and coherent temporal intensity variations. These auroras, with a roughly stationary geometry and rapid periodic variations occurring in phase, are called changing auroras. They are classified as auroras forms R according to the International Atlas of Auroras A more detailed subdivision of the changing auroras:
R 1 (pulsating aurora) is a glow with uniform phase variations in brightness throughout the form of the aurora. By definition, in an ideal pulsating aurora, the spatial and temporal parts of the pulsation can be separated, i.e. brightness I(r,t)= I s(r)· I T(t). In a typical aurora R 1, pulsations occur with a frequency of 0.01 to 10 Hz of low intensity (1–2 kR). Most auroras R 1 are spots or arcs that pulsate with a period of several seconds.
R 2 (fiery aurora). This term is usually used to refer to movements like flames filling the sky, and not to describe a single form. The auroras are arc-shaped and usually move upward from a height of 100 km. These auroras are relatively rare and occur more often outside of the auroras.
R 3 (flickering aurora). These are auroras with rapid, irregular or regular variations in brightness, giving the impression of a flickering flame in the sky. They appear shortly before the collapse of the aurora. Commonly observed variation frequency R 3 is equal to 10 ± 3 Hz.
The term streaming aurora, used for another class of pulsating auroras, refers to irregular variations in brightness moving rapidly horizontally in arcs and bands of auroras.
The changing aurora is one of the solar-terrestrial phenomena accompanying the pulsations of the geomagnetic field and auroral X-ray radiation caused by the precipitation of particles of solar and magnetospheric origin.
The glow of the polar cap is characterized by a high intensity of the band of the first negative N + 2 system (λ 3914 Å). Usually, these N + 2 bands are five times more intense than the green line OI l 5577 Å; the absolute intensity of the polar cap glow is from 0.1 to 10 kRl (usually 1–3 kRl). With these auroras, which appear during PCA periods, a uniform glow covers the entire polar cap up to the geomagnetic latitude of 60° at altitudes of 30 to 80 km. It is generated mainly by solar protons and d-particles with energies of 10–100 MeV, which create an ionization maximum at these heights. There is another type of glow in the aurora zones, called mantle auroras. For this type of auroral glow, the daily intensity maximum in the morning hours is 1–10 kR, and the intensity minimum is five times weaker. Observations of mantle auroras are few and their intensity depends on geomagnetic and solar activity.
Atmospheric glow is defined as radiation produced and emitted by a planet's atmosphere. This is the non-thermal radiation of the atmosphere, with the exception of the emission of auroras, lightning discharges and the emission of meteor trails. This term is used in relation to the earth's atmosphere (night glow, twilight glow and day glow). Atmospheric glow is only a fraction of the light available in the atmosphere. Other sources are starlight, zodiacal light, and daytime scattered light from the Sun. At times, the glow of the atmosphere can be up to 40% of the total amount of light. Airglow occurs in atmospheric layers of varying height and thickness. The atmospheric glow spectrum covers wavelengths from 1000 Å to 22.5 µm. The main emission line in the airglow is l 5577 Å, which appears at a height of 90–100 km in a layer 30–40 km thick. The appearance of the glow is due to the Champen mechanism based on the recombination of oxygen atoms. Other emission lines are l 6300 Å, appearing in the case of dissociative O + 2 recombination and emission NI l 5198/5201 Å and NI l 5890/5896 Å.
The intensity of atmospheric glow is measured in Rayleighs. The brightness (in Rayleighs) is equal to 4 rb, where c is the angular surface of the luminance of the emitting layer in units of 10 6 photon/(cm 2 sr s). The glow intensity depends on latitude (differently for different emissions), and also varies during the day with a maximum near midnight. A positive correlation was noted for the airglow in the l 5577 Å emission with the number sunspots and the flux of solar radiation at a wavelength of 10.7 cm. The glow of the atmosphere is observed during satellite experiments. From outer space, it looks like a ring of light around the Earth and has a greenish color.
Ozonosphere.
At altitudes of 20–25 km, the maximum concentration of a negligible amount of ozone O 3 (up to 2×10–7 of the oxygen content!), which occurs under the action of solar ultraviolet radiation at altitudes of about 10 to 50 km, is reached, protecting the planet from ionizing solar radiation. Despite the extremely small number of ozone molecules, they protect all life on Earth from the harmful effects of short-wave (ultraviolet and X-ray) radiation from the Sun. If you precipitate all the molecules to the base of the atmosphere, you get a layer no more than 3–4 mm thick! At altitudes above 100 km, the proportion of light gases increases, and at very high altitudes, helium and hydrogen predominate; many molecules dissociate into separate atoms, which, being ionized under the influence of hard solar radiation, form the ionosphere. The pressure and density of air in the Earth's atmosphere decrease with height. Depending on the distribution of temperature, the Earth's atmosphere is divided into the troposphere, stratosphere, mesosphere, thermosphere and exosphere. .
At an altitude of 20-25 km is located ozone layer. Ozone is formed due to the decay of oxygen molecules during the absorption of solar ultraviolet radiation with wavelengths shorter than 0.1–0.2 microns. Free oxygen combines with O 2 molecules and forms O 3 ozone, which greedily absorbs all ultraviolet light shorter than 0.29 microns. Ozone molecules O 3 are easily destroyed by short-wave radiation. Therefore, despite its rarefaction, the ozone layer effectively absorbs the ultraviolet radiation of the Sun, which has passed through the higher and more transparent atmospheric layers. Thanks to this, living organisms on Earth are protected from the harmful effects of ultraviolet light from the Sun.
Ionosphere.
Solar radiation ionizes the atoms and molecules of the atmosphere. The degree of ionization becomes significant already at an altitude of 60 kilometers and steadily increases with distance from the Earth. At different altitudes in the atmosphere, successive processes of dissociation of various molecules and subsequent ionization of various atoms and ions occur. Basically, these are oxygen molecules O 2, nitrogen N 2 and their atoms. Depending on the intensity of these processes, various layers of the atmosphere lying above 60 kilometers are called ionospheric layers. , and their totality is the ionosphere . The lower layer, the ionization of which is insignificant, is called the neutrosphere.
The maximum concentration of charged particles in the ionosphere is reached at altitudes of 300–400 km.
History of the study of the ionosphere.
The hypothesis of the existence of a conductive layer in the upper atmosphere was put forward in 1878 by the English scientist Stuart to explain the features of the geomagnetic field. Then in 1902, independently of each other, Kennedy in the USA and Heaviside in England pointed out that in order to explain the propagation of radio waves over long distances, it is necessary to assume the existence of regions with high conductivity in the high layers of the atmosphere. In 1923, Academician M.V. Shuleikin, considering the features of the propagation of radio waves of various frequencies, came to the conclusion that there are at least two reflective layers in the ionosphere. Then, in 1925, the English researchers Appleton and Barnet, as well as Breit and Tuve, experimentally proved for the first time the existence of regions that reflect radio waves, and laid the foundation for their systematic study. Since that time, a systematic study of the properties of these layers, generally called the ionosphere, has been carried out, playing a significant role in a number of geophysical phenomena that determine the reflection and absorption of radio waves, which is very important for practical purposes, in particular, to ensure reliable radio communications.
In the 1930s, systematic observations of the state of the ionosphere began. In our country, on the initiative of M.A. Bonch-Bruevich, installations for its pulsed sounding were created. Many have been explored general properties ionosphere, heights and electron concentration of its main layers.
At altitudes of 60–70 km, the D layer is observed; at altitudes of 100–120 km, the E, at altitudes, at altitudes of 180–300 km double layer F 1 and F 2. The main parameters of these layers are given in Table 4.
Table 4 | ||||||
Ionosphere region | Maximum height, km | T i , K | Day | Night ne , cm -3 | a΄, ρm 3 s – 1 | |
min ne , cm -3 | Max ne , cm -3 | |||||
D | 70 | 20 | 100 | 200 | 10 | 10 –6 |
E | 110 | 270 | 1.5 10 5 | 3 10 5 | 3000 | 10 –7 |
F 1 | 180 | 800–1500 | 3 10 5 | 5 10 5 | – | 3 10 -8 |
F 2 (winter) | 220–280 | 1000–2000 | 6 10 5 | 25 10 5 | ~10 5 | 2 10 –10 |
F 2 (summer) | 250–320 | 1000–2000 | 2 10 5 | 8 10 5 | ~3 10 5 | 10 –10 |
ne is the electron concentration, e is the electron charge, T i is the ion temperature, a΄ is the recombination coefficient (which determines the ne and its change over time) |
Averages are given as they vary for different latitudes, times of day and seasons. Such data is necessary to ensure long-range radio communications. They are used in selecting operating frequencies for various shortwave radio links. Knowing their change depending on the state of the ionosphere at different times of the day and in different seasons is extremely important for ensuring the reliability of radio communications. The ionosphere is a collection of ionized layers of the earth's atmosphere, starting at altitudes of about 60 km and extending to altitudes of tens of thousands of km. The main source of ionization of the Earth's atmosphere is the ultraviolet and X-ray radiation of the Sun, which occurs mainly in the solar chromosphere and corona. In addition, the degree of ionization of the upper atmosphere is affected by solar corpuscular streams that occur during solar flares, as well as cosmic rays and meteor particles.
Ionospheric layers
are areas in the atmosphere in which the maximum values of the concentration of free electrons are reached (i.e. their number per unit volume). Electrically charged free electrons and (to a lesser extent, less mobile ions) resulting from the ionization of atmospheric gas atoms, interacting with radio waves (i.e. electromagnetic oscillations), can change their direction, reflecting or refracting them, and absorb their energy. As a result, when receiving distant radio stations, various effects may occur, for example, radio fading, increased audibility of distant stations, blackouts and so on. phenomena.
Research methods.
Classical methods of studying the ionosphere from the Earth are reduced to pulse sounding - sending radio pulses and observing their reflections from various layers of the ionosphere with measuring the delay time and studying the intensity and shape of the reflected signals. By measuring the heights of reflection of radio pulses at different frequencies, determining the critical frequencies of various regions (the carrier frequency of the radio pulse for which this region of the ionosphere becomes transparent is called critical), it is possible to determine the value of the electron density in the layers and the effective heights for given frequencies, and choose the optimal frequencies for given radio paths. With the development of rocket technology and the advent of the space age of artificial Earth satellites (AES) and other spacecraft, it became possible to directly measure the parameters of the near-Earth space plasma, the lower part of which is the ionosphere.
Electron density measurements carried out from specially launched rockets and along satellite flight paths confirmed and refined data previously obtained by ground-based methods on the structure of the ionosphere, the distribution of electron density with height over different regions of the Earth, and made it possible to obtain electron density values above the main maximum - the layer F. Previously, it was impossible to do this by sounding methods based on observations of reflected short-wavelength radio pulses. It has been found that in some regions of the globe there are fairly stable regions with low electron density, regular “ionospheric winds”, peculiar wave processes arise in the ionosphere that carry local ionospheric disturbances thousands of kilometers from the place of their excitation, and much more. The creation of especially highly sensitive receiving devices made it possible to carry out at the stations of pulsed sounding of the ionosphere the reception of pulsed signals partially reflected from the lowest regions of the ionosphere (station of partial reflections). The use of powerful pulse installations in the meter and decimeter wave bands with the use of antennas that make it possible to carry out a high concentration of radiated energy made it possible to observe signals scattered by the ionosphere at various heights. The study of the features of the spectra of these signals, incoherently scattered by electrons and ions of the ionospheric plasma (for this, stations of incoherent scattering of radio waves were used) made it possible to determine the concentration of electrons and ions, their equivalent temperature at various altitudes up to altitudes of several thousand kilometers. It turned out that the ionosphere is sufficiently transparent for the frequencies used.
Concentration electric charges(the electron density is equal to the ion one) in the earth's ionosphere at a height of 300 km is about 106 cm–3 during the day. A plasma of this density reflects radio waves longer than 20 m, while transmitting shorter ones.
Typical vertical distribution of electron density in the ionosphere for day and night conditions.
Propagation of radio waves in the ionosphere.
The stable reception of long-range broadcasting stations depends on the frequencies used, as well as on the time of day, season and, in addition, on solar activity. Solar activity significantly affects the state of the ionosphere. Radio waves emitted by a ground station propagate in a straight line, like all types of electromagnetic waves. However, it should be taken into account that both the surface of the Earth and the ionized layers of its atmosphere serve as a kind of plates of a huge capacitor, acting on them like the action of mirrors on light. Reflected from them, radio waves can travel many thousands of kilometers, bending around the globe in huge leaps of hundreds and thousands of kilometers, reflecting alternately from a layer of ionized gas and from the surface of the Earth or water.
In the 1920s, it was believed that radio waves shorter than 200 m were generally not suitable for long-distance communications due to strong absorption. The first experiments on long-range reception of short waves across the Atlantic between Europe and America were carried out English physicist Oliver Heaviside and American electrical engineer Arthur Kennelly. Independently of each other, they suggested that somewhere around the Earth there is an ionized layer of the atmosphere that can reflect radio waves. It was called the Heaviside layer - Kennelly, and then - the ionosphere.
According to modern ideas the ionosphere consists of negatively charged free electrons and positively charged ions, mainly molecular oxygen O + and nitric oxide NO + . Ions and electrons are formed as a result of the dissociation of molecules and the ionization of neutral gas atoms by solar X-ray and ultraviolet radiation. In order to ionize an atom, it is necessary to inform it of ionization energy, the main source of which for the ionosphere is the ultraviolet, X-ray and corpuscular radiation of the Sun.
As long as the gas shell of the Earth is illuminated by the Sun, more and more electrons are continuously formed in it, but at the same time, some of the electrons, colliding with ions, recombine, again forming neutral particles. After sunset, the production of new electrons almost stops, and the number of free electrons begins to decrease. The more free electrons in the ionosphere, the better high-frequency waves are reflected from it. With a decrease in the electron concentration, the passage of radio waves is possible only in low-frequency ranges. That is why at night, as a rule, it is possible to receive distant stations only in the ranges of 75, 49, 41 and 31 m. Electrons are distributed unevenly in the ionosphere. At an altitude of 50 to 400 km, there are several layers or regions of increased electron density. These areas smoothly transition into one another and affect the propagation of HF radio waves in different ways. The upper layer of the ionosphere is denoted by the letter F. Here is the highest degree of ionization (the fraction of charged particles is about 10–4). It is located at an altitude of more than 150 km above the Earth's surface and plays the main reflective role in the long-range propagation of radio waves of high-frequency HF bands. In the summer months, the F region breaks up into two layers - F 1 and F 2. The F1 layer can occupy heights from 200 to 250 km, and the layer F 2 seems to “float” in the altitude range of 300–400 km. Usually layer F 2 is ionized much stronger than the layer F 1 . night layer F 1 disappears and layer F 2 remains, slowly losing up to 60% of its degree of ionization. Below the F layer, at altitudes from 90 to 150 km, there is a layer E, whose ionization occurs under the influence of soft X-ray radiation from the Sun. The degree of ionization of the E layer is lower than that of the F, during the day, reception of stations of low-frequency HF bands of 31 and 25 m occurs when signals are reflected from the layer E. Usually these are stations located at a distance of 1000–1500 km. At night in a layer E ionization sharply decreases, but even at this time it continues to play a significant role in the reception of signals from stations in the bands 41, 49 and 75 m.
Of great interest for receiving signals of high-frequency HF bands of 16, 13 and 11 m are those arising in the area E interlayers (clouds) of strongly increased ionization. The area of these clouds can vary from a few to hundreds of square kilometers. This layer of increased ionization is called the sporadic layer. E and denoted Es. Es clouds can move in the ionosphere under the influence of wind and reach speeds of up to 250 km/h. In summer, in the middle latitudes during the daytime, the origin of radio waves due to Es clouds occurs 15–20 days per month. Near the equator, it is almost always present, and at high latitudes it usually appears at night. Sometimes, in the years of low solar activity, when there is no passage to the high-frequency HF bands, distant stations suddenly appear with good loudness on the bands of 16, 13 and 11 m, the signals of which were repeatedly reflected from Es.
The lowest region of the ionosphere is the region D located at altitudes between 50 and 90 km. There are relatively few free electrons here. From area D long and medium waves are well reflected, and the signals of low-frequency HF stations are strongly absorbed. After sunset, ionization disappears very quickly and it becomes possible to receive distant stations in the ranges of 41, 49 and 75 m, the signals of which are reflected from the layers F 2 and E. Separate layers of the ionosphere play an important role in the propagation of HF radio signals. The impact on radio waves is mainly due to the presence of free electrons in the ionosphere, although the propagation mechanism of radio waves is associated with the presence of large ions. The latter are also of interest in the study of the chemical properties of the atmosphere, since they are more active than neutral atoms and molecules. Chemical reactions occurring in the ionosphere play an important role in its energy and electrical balance.
normal ionosphere. Observations carried out with the help of geophysical rockets and satellites have given a lot of new information, indicating that the ionization of the atmosphere occurs under the influence of broad-spectrum solar radiation. Its main part (more than 90%) is concentrated in the visible part of the spectrum. Ultraviolet radiation with a shorter wavelength and more energy than violet light rays is emitted by the hydrogen of the inner part of the Sun's atmosphere (chromosphere), and X-ray radiation, which has even higher energy, is emitted by the gases of the Sun's outer shell (corona).
The normal (average) state of the ionosphere is due to constant powerful radiation. Regular changes occur in the normal ionosphere under the influence of the daily rotation of the Earth and seasonal differences in the angle of incidence of the sun's rays at noon, but unpredictable and abrupt changes in the state of the ionosphere also occur.
Disturbances in the ionosphere.
As is known, powerful cyclically repeating manifestations of activity occur on the Sun, which reach a maximum every 11 years. Observations under the program of the International Geophysical Year (IGY) coincided with the period of the highest solar activity for the entire period of systematic meteorological observations, i.e. from the beginning of the 18th century. During periods of high activity, the brightness of some areas on the Sun increases several times, and the power of ultraviolet and X-ray radiation increases sharply. Such phenomena are called solar flares. They last from several minutes to one or two hours. During a flare, solar plasma erupts (mainly protons and electrons), and elementary particles rush into outer space. The electromagnetic and corpuscular radiation of the Sun at the moments of such flares has strong impact to the Earth's atmosphere.
The initial reaction is noted 8 minutes after the flash, when intense ultraviolet and X-ray radiation reaches the Earth. As a result, ionization sharply increases; x-rays penetrate the atmosphere to the lower boundary of the ionosphere; the number of electrons in these layers increases so much that the radio signals are almost completely absorbed ("extinguished"). Additional absorption of radiation causes heating of the gas, which contributes to the development of winds. Ionized gas is an electrical conductor, and when it moves in the Earth's magnetic field, the dynamo effect appears and arises electricity. Such currents can, in turn, cause noticeable perturbations of the magnetic field and manifest themselves in the form of magnetic storms.
The structure and dynamics of the upper atmosphere is essentially determined by thermodynamically nonequilibrium processes associated with ionization and dissociation by solar radiation, chemical processes, excitation of molecules and atoms, their deactivation, collision, and other elementary processes. In this case, the degree of nonequilibrium increases with height as the density decreases. Up to altitudes of 500–1000 km, and often even higher, the degree of nonequilibrium for many characteristics of the upper atmosphere is quite small, which allows one to use classical and hydromagnetic hydrodynamics with allowance for chemical reactions to describe it.
The exosphere is the outer layer of the Earth's atmosphere, starting at altitudes of several hundred kilometers, from which light, fast-moving hydrogen atoms can escape into outer space.
Edward Kononovich
Literature:
Pudovkin M.I. Fundamentals of solar physics. St. Petersburg, 2001
Eris Chaisson, Steve McMillan Astronomy today. Prentice Hall Inc. Upper Saddle River, 2002
Online materials: http://ciencia.nasa.gov/
Space is filled with energy. Energy fills space unevenly. There are places of its concentration and discharge. This way you can estimate the density. The planet is an ordered system, with the maximum density of matter in the center and with a gradual decrease in concentration towards the periphery. Interaction forces determine the state of matter, the form in which it exists. Physics describes the state of aggregation of substances: solid, liquid, gas, and so on.
The atmosphere is the gaseous medium that surrounds the planet. The Earth's atmosphere allows free movement and allows light to pass through, creating a space in which life thrives.
The area from the earth's surface to a height of approximately 16 kilometers (less from the equator to the poles, also depends on the season) is called the troposphere. The troposphere is the layer that contains about 80% of the air in the atmosphere and almost all of the water vapor. It is here that the processes that shape the weather take place. Pressure and temperature decrease with height. The reason for the decrease in air temperature is an adiabatic process, when the gas expands, it cools. At the upper boundary of the troposphere, values can reach -50, -60 degrees Celsius.
Next comes the Stratosphere. It extends up to 50 kilometers. In this layer of the atmosphere, the temperature increases with height, acquiring a value at the top point of about 0 C. The temperature increase is caused by the process of absorption of ultraviolet rays by the ozone layer. Radiation causes a chemical reaction. Oxygen molecules break down into single atoms that can combine with normal oxygen molecules to form ozone.
Radiation from the sun with wavelengths between 10 and 400 nanometers is classified as ultraviolet. The shorter the wavelength of UV radiation, the greater the danger it poses to living organisms. Only a small fraction of the radiation reaches the Earth's surface, moreover, the less active part of its spectrum. This feature of nature allows a person to get a healthy sun tan.
The next layer of the atmosphere is called the Mesosphere. Limits from approximately 50 km to 85 km. In the mesosphere, the concentration of ozone, which could trap UV energy, is low, so the temperature begins to fall again with height. At the peak point, the temperature drops to -90 C, some sources indicate a value of -130 C. Most meteoroids burn up in this layer of the atmosphere.
The layer of the atmosphere that stretches from a height of 85 km to a distance of 600 km from the Earth is called the Thermosphere. The thermosphere is the first to encounter solar radiation, including the so-called vacuum ultraviolet.
Vacuum UV is delayed by the air, thereby heating this layer of the atmosphere to enormous temperatures. However, since the pressure here is extremely low, this seemingly incandescent gas does not have the same effect on objects as it does under conditions on the earth's surface. On the contrary, objects placed in such an environment will cool down.
At an altitude of 100 km, the conditional line "Karman line" passes, which is considered to be the beginning of space.
Auroras occur in the thermosphere. In this layer of the atmosphere, the solar wind interacts with the planet's magnetic field.
The last layer of the atmosphere is the Exosphere, an outer shell that stretches for thousands of kilometers. The exosphere is practically an empty place, however, the number of atoms wandering here is an order of magnitude greater than in interplanetary space.
The person breathes air. Normal pressure is 760 millimeters of mercury. At an altitude of 10,000 m, the pressure is about 200 mm. rt. Art. At this altitude, a person can probably breathe, at least not for a long time, but this requires preparation. The state will obviously be inoperable.
The gas composition of the atmosphere: 78% nitrogen, 21% oxygen, about a percent argon, everything else is a mixture of gases representing the smallest fraction of the total.
The atmosphere is a mixture of various gases. It extends from the surface of the Earth to a height of up to 900 km, protecting the planet from the harmful spectrum of solar radiation, and contains gases necessary for all life on the planet. The atmosphere traps the heat of the sun, warming near the earth's surface and creating a favorable climate.
Composition of the atmosphere
The Earth's atmosphere consists mainly of two gases - nitrogen (78%) and oxygen (21%). In addition, it contains impurities of carbon dioxide and other gases. in the atmosphere exists in the form of vapor, drops of moisture in clouds and ice crystals.
Layers of the atmosphere
The atmosphere consists of many layers, between which there are no clear boundaries. The temperatures of different layers differ markedly from each other.
- airless magnetosphere. Most of the Earth's satellites fly here outside the Earth's atmosphere.
- Exosphere (450-500 km from the surface). Almost does not contain gases. Some weather satellites fly in the exosphere. The thermosphere (80-450 km) is characterized by high temperatures reaching 1700°C in the upper layer.
- Mesosphere (50-80 km). In this sphere, the temperature drops as the altitude increases. It is here that most of the meteorites (fragments of space rocks) that enter the atmosphere burn down.
- Stratosphere (15-50 km). Contains an ozone layer, i.e. a layer of ozone that absorbs ultraviolet radiation from the sun. This leads to an increase in temperature near the Earth's surface. They usually fly here. jet aircraft, because visibility in this layer is very good and there is almost no interference caused by weather conditions.
- Troposphere. The height varies from 8 to 15 km from the earth's surface. It is here that the weather of the planet is formed, since in this layer contains the most water vapor, dust and winds. The temperature decreases with distance from the earth's surface.
Atmosphere pressure
Although we do not feel it, the layers of the atmosphere exert pressure on the surface of the Earth. The highest is near the surface, and as you move away from it, it gradually decreases. It depends on the temperature difference between land and ocean, and therefore in areas located at the same height above sea level, there is often a different pressure. Low pressure brings wet weather, while high pressure usually sets clear weather.
The movement of air masses in the atmosphere
And the pressures cause the lower atmosphere to mix. This creates winds that blow from areas of high pressure to areas of low pressure. In many regions, local winds also occur, caused by differences in land and sea temperatures. Mountains also have a significant influence on the direction of the winds.
Greenhouse effect
Carbon dioxide and other gases in the earth's atmosphere trap the sun's heat. This process is commonly called the greenhouse effect, as it is in many ways similar to the circulation of heat in greenhouses. The greenhouse effect causes global warming on the planet. In areas of high pressure - anticyclones - a clear solar one is established. In areas of low pressure - cyclones - the weather is usually unstable. Heat and light entering the atmosphere. The gases trap the heat reflected from the earth's surface, thereby causing the temperature on the earth to rise.
There is a special ozone layer in the stratosphere. Ozone blocks most of the ultraviolet radiation from the Sun, protecting the Earth and all life on it from it. Scientists have found that the cause of the destruction of the ozone layer are special chlorofluorocarbon dioxide gases contained in some aerosols and refrigeration equipment. Over the Arctic and Antarctica, huge holes have been found in the ozone layer, contributing to an increase in the amount of ultraviolet radiation affecting the Earth's surface.
Ozone is formed in the lower atmosphere as a result between solar radiation and various exhaust fumes and gases. Usually it disperses through the atmosphere, but if a closed layer of cold air forms under a layer of warm air, ozone concentrates and smog occurs. Unfortunately, this cannot make up for the loss of ozone in the ozone holes.
The satellite image clearly shows a hole in the ozone layer over Antarctica. The size of the hole varies, but scientists believe that it is constantly increasing. Attempts are being made to reduce the level of exhaust gases in the atmosphere. Reduce air pollution and use smokeless fuels in cities. Smog causes eye irritation and choking in many people.
The emergence and evolution of the Earth's atmosphere
The modern atmosphere of the Earth is the result of a long evolutionary development. It arose as a result of the joint action of geological factors and the vital activity of organisms. Throughout geological history, the earth's atmosphere has gone through several profound rearrangements. On the basis of geological data and theoretical (prerequisites), the primordial atmosphere of the young Earth, which existed about 4 billion years ago, could consist of a mixture of inert and noble gases with a small addition of passive nitrogen (N. A. Yasamanov, 1985; A. S. Monin, 1987; O. G. Sorokhtin, S. A. Ushakov, 1991, 1993. At present, the view on the composition and structure of the early atmosphere has somewhat changed. The primary atmosphere (protoatmosphere) at the earliest protoplanetary stage., i.e. older 4.2 billion years, could consist of a mixture of methane, ammonia and carbon dioxide.As a result of mantle degassing and flowing on the earth's surface active processes weathering, water vapor, carbon compounds in the form of CO 2 and CO, sulfur and its compounds, as well as strong halogen acids - HCI, HF, HI and boric acid, which were supplemented by methane, ammonia, hydrogen, argon and some other noble gases. This primordial atmosphere was extremely thin. Therefore, the temperature near the earth's surface was close to the temperature of radiative equilibrium (AS Monin, 1977).
Over time, the gas composition of the primary atmosphere began to transform under the influence of the processes of weathering of rocks protruding on the earth's surface, the vital activity of cyanobacteria and blue-green algae, volcanic processes and the action of sunlight. This led to the decomposition of methane into and carbon dioxide, ammonia - into nitrogen and hydrogen; carbon dioxide began to accumulate in the secondary atmosphere, which slowly descended to the earth's surface, and nitrogen. Thanks to the vital activity of blue-green algae, oxygen began to be produced in the process of photosynthesis, which, however, at the beginning was mainly spent on “oxidizing atmospheric gases, and then rocks. At the same time, ammonia, oxidized to molecular nitrogen, began to intensively accumulate in the atmosphere. It is assumed that a significant part of the nitrogen in the modern atmosphere is relict. Methane and carbon monoxide were oxidized to carbon dioxide. Sulfur and hydrogen sulfide were oxidized to SO 2 and SO 3, which, due to their high mobility and lightness, were quickly removed from the atmosphere. Thus, the atmosphere from a reducing one, as it was in the Archean and early Proterozoic, gradually turned into an oxidizing one.
Carbon dioxide entered the atmosphere both as a result of methane oxidation and as a result of degassing of the mantle and weathering of rocks. In the event that all the carbon dioxide released over the entire history of the Earth remained in the atmosphere, its partial pressure could now become the same as on Venus (O. Sorokhtin, S. A. Ushakov, 1991). But on Earth, the process was reversed. A significant part of carbon dioxide from the atmosphere was dissolved in the hydrosphere, in which it was used by aquatic organisms to build their shells and biogenically converted into carbonates. Subsequently, the most powerful strata of chemogenic and organogenic carbonates were formed from them.
Oxygen was supplied to the atmosphere from three sources. For a long time, starting from the moment of the formation of the Earth, it was released during the degassing of the mantle and was mainly spent on oxidative processes. Another source of oxygen was the photodissociation of water vapor by hard ultraviolet solar radiation. appearances; free oxygen in the atmosphere led to the death of most of the prokaryotes that lived in reducing conditions. Prokaryotic organisms have changed their habitats. They left the surface of the Earth to its depths and regions where reducing conditions were still preserved. They were replaced by eukaryotes, which began to vigorously process carbon dioxide into oxygen.
During the Archean and a significant part of the Proterozoic, almost all oxygen, arising both abiogenically and biogenically, was mainly spent on the oxidation of iron and sulfur. By the end of the Proterozoic, all the metallic divalent iron that was on the earth's surface either oxidized or moved into the earth's core. This led to the fact that the partial pressure of oxygen in the early Proterozoic atmosphere changed.
In the middle of the Proterozoic, the concentration of oxygen in the atmosphere reached the Urey point and amounted to 0.01% of the current level. Starting from that time, oxygen began to accumulate in the atmosphere and, probably, already at the end of the Riphean, its content reached the Pasteur point (0.1% of the current level). It is possible that the ozone layer arose in the Vendian period and that time it never disappeared.
The appearance of free oxygen in the earth's atmosphere stimulated the evolution of life and led to the emergence of new forms with a more perfect metabolism. If earlier eukaryotic unicellular algae and cyanides, which appeared at the beginning of the Proterozoic, required an oxygen content in water of only 10 -3 of its modern concentration, then with the emergence of non-skeletal Metazoa at the end of the Early Vendian, i.e., about 650 million years ago, the oxygen concentration in the atmosphere should have been much higher. After all, Metazoa used oxygen respiration and for this it was required that the partial pressure of oxygen reached critical level- Pasteur points. In this case, the anaerobic fermentation process was replaced by an energetically more promising and progressive oxygen metabolism.
After that, the further accumulation of oxygen in the earth's atmosphere occurred rather rapidly. The progressive increase in the volume of blue-green algae contributed to the achievement in the atmosphere of the oxygen level necessary for the life support of the animal world. A certain stabilization of the oxygen content in the atmosphere has occurred since the moment when the plants came to land - about 450 million years ago. The emergence of plants on land, which occurred in the Silurian period, led to the final stabilization of the level of oxygen in the atmosphere. Since that time, its concentration began to fluctuate within rather narrow limits, never going beyond the existence of life. The concentration of oxygen in the atmosphere has completely stabilized since the appearance of flowering plants. This event took place in the middle of the Cretaceous period, i.e. about 100 million years ago.
The bulk of nitrogen was formed in the early stages of the Earth's development, mainly due to the decomposition of ammonia. With the advent of organisms, the process of binding atmospheric nitrogen into organic matter and burial in marine sediments. After the release of organisms on land, nitrogen began to be buried in continental sediments. The processes of processing free nitrogen were especially intensified with the advent of terrestrial plants.
At the turn of the Cryptozoic and Phanerozoic, i.e., about 650 million years ago, the carbon dioxide content in the atmosphere decreased to tenths of a percent, and it reached a content close to the current level only quite recently, about 10-20 million years ago.
Thus, the gas composition of the atmosphere not only provided living space for organisms, but also determined the characteristics of their vital activity, promoted settlement and evolution. The resulting failures in the distribution of the atmospheric gas composition favorable for organisms, both due to cosmic and planetary causes, led to mass extinctions of the organic world, which repeatedly occurred during the Cryptozoic and at certain boundaries of the Phanerozoic history.
Ethnospheric functions of the atmosphere
The Earth's atmosphere provides the necessary substance, energy and determines the direction and speed of metabolic processes. The gas composition of the modern atmosphere is optimal for the existence and development of life. As an area of weather and climate formation, the atmosphere must create comfortable conditions for the life of people, animals and vegetation. Deviations in one direction or another in the quality of atmospheric air and weather conditions create extreme conditions for the life of the animal and flora, including for humans.
The atmosphere of the Earth not only provides the conditions for the existence of mankind, being the main factor in the evolution of the ethnosphere. At the same time, it turns out to be an energy and raw material resource for production. In general, the atmosphere is a factor that preserves human health, and some areas, due to physical and geographical conditions and atmospheric air quality, serve as recreational areas and are areas intended for sanatorium treatment and recreation for people. Thus, the atmosphere is a factor of aesthetic and emotional impact.
The ethnospheric and technospheric functions of the atmosphere, determined quite recently (E. D. Nikitin, N. A. Yasamanov, 2001), need an independent and in-depth study. Thus, the study of atmospheric energy functions is very relevant both in terms of the occurrence and operation of processes that damage the environment, and in terms of the impact on human health and well-being. In this case we are talking about the energy of cyclones and anticyclones, atmospheric vortices, atmospheric pressure and other extreme atmospheric phenomena, the effective use of which will contribute to the successful solution of the problem of obtaining non-polluting environment alternative energy sources. After all, the air environment, especially that part of it that is located above the World Ocean, is an area for the release of a colossal amount of free energy.
For example, it has been established that tropical cyclones of average strength release energy equivalent to the energy of 500 thousand tons per day only. atomic bombs dropped on Hiroshima and Nagasaki. For 10 days of the existence of such a cyclone, enough energy is released to meet all the energy needs of a country like the United States for 600 years.
IN last years A large number of works by natural scientists have been published, in one way or another concerning various aspects of activity and the influence of the atmosphere on earth processes, which indicates the intensification of interdisciplinary interactions in modern natural science. At the same time, the integrating role of certain of its directions is manifested, among which it is necessary to note the functional-ecological direction in geoecology.
This direction stimulates the analysis and theoretical generalization of the ecological functions and the planetary role of various geospheres, and this, in turn, is an important prerequisite for the development of methodology and scientific foundations for a holistic study of our planet, the rational use and protection of its natural resources.
The Earth's atmosphere consists of several layers: troposphere, stratosphere, mesosphere, thermosphere, ionosphere and exosphere. In the upper part of the troposphere and the lower part of the stratosphere there is a layer enriched with ozone, called the ozone layer. Certain (daily, seasonal, annual, etc.) regularities in the distribution of ozone have been established. Since its inception, the atmosphere has influenced the course of planetary processes. The primary composition of the atmosphere was completely different than at present, but over time the proportion and role of molecular nitrogen steadily increased, about 650 million years ago free oxygen appeared, the amount of which continuously increased, but the concentration of carbon dioxide decreased accordingly. The high mobility of the atmosphere, its gas composition and the presence of aerosols determine its outstanding role and active participation in various geological and biospheric processes. The role of the atmosphere in the redistribution of solar energy and the development of catastrophic natural phenomena and disasters is great. Negative impact on organic world and natural systems render atmospheric whirlwinds - tornadoes (tornadoes), hurricanes, typhoons, cyclones and other phenomena. The main sources of pollution along with natural factors are various forms economic activity person. Anthropogenic impacts on the atmosphere are expressed not only in the appearance of various aerosols and greenhouse gases, but also in an increase in the amount of water vapor, and manifest themselves in the form of smog and acid rain. Greenhouse gases change the temperature regime of the earth's surface, emissions of certain gases reduce the volume of the ozone screen and contribute to the formation of ozone holes. The ethnospheric role of the Earth's atmosphere is great.
The role of the atmosphere in natural processes
The surface atmosphere in its intermediate state between the lithosphere and outer space and its gas composition creates conditions for the life of organisms. At the same time, the weathering and intensity of destruction of rocks, the transfer and accumulation of detrital material depend on the amount, nature and frequency of precipitation, on the frequency and strength of winds, and especially on air temperature. The atmosphere is the central component of the climate system. Air temperature and humidity, cloudiness and precipitation, wind - all this characterizes the weather, that is, the continuously changing state of the atmosphere. At the same time, these same components also characterize the climate, i.e., the average long-term weather regime.
The composition of gases, the presence of clouds and various impurities, which are called aerosol particles (ash, dust, particles of water vapor), determine the characteristics of the passage of solar radiation through the atmosphere and prevent the escape of the Earth's thermal radiation into outer space.
The Earth's atmosphere is very mobile. The processes arising in it and changes in its gas composition, thickness, cloudiness, transparency and the presence of various aerosol particles in it affect both the weather and the climate.
The action and direction of natural processes, as well as life and activity on Earth, are determined by solar radiation. It gives 99.98% of the heat coming to the earth's surface. Annually it makes 134*10 19 kcal. This amount of heat can be obtained by burning 200 billion tons of coal. The reserves of hydrogen, which creates this flow of thermonuclear energy in the mass of the Sun, will be enough for at least another 10 billion years, i.e., for a period twice as long as our planet itself exists.
About 1/3 of the total amount of solar energy entering the upper boundary of the atmosphere is reflected back into the world space, 13% is absorbed by the ozone layer (including almost all ultraviolet radiation). 7% - the rest of the atmosphere and only 44% reaches the earth's surface. The total solar radiation reaching the Earth in a day is equal to the energy that humanity has received as a result of burning all types of fuel over the past millennium.
The amount and nature of the distribution of solar radiation on the earth's surface are closely dependent on the cloudiness and transparency of the atmosphere. The amount of scattered radiation is affected by the height of the Sun above the horizon, the transparency of the atmosphere, the content of water vapor, dust, the total amount of carbon dioxide, etc.
The maximum amount of scattered radiation falls into the polar regions. The lower the Sun is above the horizon, the less heat enters a given area.
Atmospheric transparency and cloudiness are of great importance. On a cloudy summer day, it is usually colder than on a clear one, since daytime clouds prevent the earth's surface from heating.
The dust content of the atmosphere plays an important role in the distribution of heat. The finely dispersed solid particles of dust and ash in it, which affect its transparency, adversely affect the distribution of solar radiation, most of which is reflected. Fine particles enter the atmosphere in two ways: either ashes thrown out during volcanic eruptions, or desert dust carried by winds from arid tropical and subtropical regions. Especially a lot of such dust is formed during droughts, when it is carried into the upper layers of the atmosphere by streams of warm air and can stay there for a long time. After the eruption of the Krakatoa volcano in 1883, dust thrown tens of kilometers into the atmosphere remained in the stratosphere for about 3 years. As a result of the 1985 eruption of the El Chichon volcano (Mexico), dust reached Europe, and therefore there was a slight decrease in surface temperatures.
The Earth's atmosphere contains a variable amount of water vapor. In absolute terms, by weight or volume, its amount ranges from 2 to 5%.
Water vapor, like carbon dioxide, enhances the greenhouse effect. In the clouds and fogs that arise in the atmosphere, peculiar physicochemical processes take place.
The primary source of water vapor in the atmosphere is the surface of the oceans. A layer of water 95 to 110 cm thick annually evaporates from it. Part of the moisture returns to the ocean after condensation, and the other is directed towards the continents by air currents. In regions with a variable-humid climate, precipitation moistens the soil, and in humid regions it creates groundwater reserves. Thus, the atmosphere is an accumulator of humidity and a reservoir of precipitation. and fogs that form in the atmosphere provide moisture to the soil cover and thus play a decisive role in the development of the animal and plant world.
Atmospheric moisture is distributed over the earth's surface due to the mobility of the atmosphere. It has a very complex system of winds and pressure distribution. Due to the fact that the atmosphere is in continuous motion, the nature and extent of the distribution of wind flows and pressure are constantly changing. The scales of circulation vary from micrometeorological, with a size of only a few hundred meters, to a global one, with a size of several tens of thousands of kilometers. Huge atmospheric vortices are involved in the creation of systems of large-scale air currents and determine the general circulation of the atmosphere. In addition, they are sources of catastrophic atmospheric phenomena.
The distribution of weather and climatic conditions and the functioning of living matter depend on atmospheric pressure. In the event that atmospheric pressure fluctuates within small limits, it does not play a decisive role in the well-being of people and the behavior of animals and does not affect the physiological functions of plants. As a rule, frontal phenomena and weather changes are associated with pressure changes.
Atmospheric pressure is of fundamental importance for the formation of wind, which, being a relief-forming factor, has the strongest effect on flora and fauna.
The wind is able to suppress the growth of plants and at the same time promotes the transfer of seeds. The role of the wind in the formation of weather and climatic conditions is great. He also acts as a regulator of sea currents. Wind as one of the exogenous factors contributes to the erosion and deflation of weathered material over long distances.
Ecological and geological role of atmospheric processes
The decrease in the transparency of the atmosphere due to the appearance of aerosol particles and solid dust in it affects the distribution of solar radiation, increasing the albedo or reflectivity. Various chemical reactions lead to the same result, causing the decomposition of ozone and the generation of "pearl" clouds, consisting of water vapor. Global change in reflectivity, as well as changes in the gas composition of the atmosphere, mainly greenhouse gases, are the cause of climate change.
Uneven heating, causing differences in atmospheric pressure over different parts of the earth's surface, leads to atmospheric circulation, which is hallmark troposphere. When there is a difference in pressure, air rushes from areas of high pressure to areas of low pressure. These movements of air masses, together with humidity and temperature, determine the main ecological and geological features of atmospheric processes.
Depending on the speed, the wind produces various geological work on the earth's surface. At a speed of 10 m/s, it shakes thick branches of trees, picks up and carries dust and fine sand; breaks tree branches at a speed of 20 m/s, carries sand and gravel; at a speed of 30 m/s (storm) tears off the roofs of houses, uproots trees, breaks poles, moves pebbles and carries small gravel, and a hurricane at a speed of 40 m/s destroys houses, breaks and demolishes power line poles, uproots large trees.
Squall storms and tornadoes (tornadoes) have a great negative environmental impact with catastrophic consequences - atmospheric vortices that occur in the warm season on powerful atmospheric fronts with a speed of up to 100 m/s. Squalls are horizontal whirlwinds with hurricane wind speeds (up to 60-80 m/s). They are often accompanied by heavy showers and thunderstorms lasting from a few minutes to half an hour. The squalls cover areas up to 50 km wide and travel a distance of 200-250 km. A heavy storm in Moscow and the Moscow region in 1998 damaged the roofs of many houses and knocked down trees.
Tornadoes, called tornadoes in North America, are powerful funnel-shaped atmospheric eddies often associated with thunderclouds. These are columns of air narrowing in the middle with a diameter of several tens to hundreds of meters. The tornado has the appearance of a funnel, very similar to an elephant's trunk, descending from the clouds or rising from the surface of the earth. Possessing a strong rarefaction and high rotation speed, the tornado travels up to several hundred kilometers, drawing in dust, water from reservoirs and various objects. Powerful tornadoes are accompanied by thunderstorms, rain and have great destructive power.
Tornadoes rarely occur in subpolar or equatorial regions, where it is constantly cold or hot. Few tornadoes in the open ocean. Tornadoes occur in Europe, Japan, Australia, the USA, and in Russia they are especially frequent in the Central Black Earth region, in the Moscow, Yaroslavl, Nizhny Novgorod and Ivanovo regions.
Tornadoes lift and move cars, houses, wagons, bridges. Particularly destructive tornadoes (tornadoes) are observed in the United States. From 450 to 1500 tornadoes are recorded annually, with an average of about 100 victims. Tornadoes are fast-acting catastrophic atmospheric processes. They are formed in just 20-30 minutes, and their existence time is 30 minutes. Therefore, it is almost impossible to predict the time and place of occurrence of tornadoes.
Other destructive, but long-term atmospheric vortices are cyclones. They are formed due to a pressure drop, which, under certain conditions, contributes to the occurrence of a circular movement of air currents. Atmospheric vortices originate around powerful ascending currents of humid warm air and rotate at high speed clockwise in the southern hemisphere and counterclockwise in the northern hemisphere. Cyclones, unlike tornadoes, originate over the oceans and produce their destructive actions over the continents. The main destructive factors are strong winds, intense precipitation in the form of snowfall, downpours, hail and surge floods. Winds with speeds of 19 - 30 m / s form a storm, 30 - 35 m / s - a storm, and more than 35 m / s - a hurricane.
Tropical cyclones - hurricanes and typhoons - have an average width of several hundred kilometers. The wind speed inside the cyclone reaches hurricane force. Tropical cyclones last from several days to several weeks, moving at a speed of 50 to 200 km/h. Mid-latitude cyclones have a larger diameter. Their transverse dimensions range from a thousand to several thousand kilometers, the wind speed is stormy. They move in the northern hemisphere from the west and are accompanied by hail and snowfall, which are catastrophic. Cyclones and their associated hurricanes and typhoons are the largest natural disasters after floods in terms of the number of victims and damage caused. In densely populated areas of Asia, the number of victims during hurricanes is measured in the thousands. In 1991, in Bangladesh, during a hurricane that caused the formation of sea waves 6 m high, 125 thousand people died. Typhoons cause great damage to the United States. As a result, dozens and hundreds of people die. In Western Europe, hurricanes cause less damage.
Thunderstorms are considered a catastrophic atmospheric phenomenon. They occur when warm, moist air rises very quickly. On the border of the tropical and subtropical zones, thunderstorms occur for 90-100 days a year, in the temperate zone for 10-30 days. In our country, the largest number of thunderstorms occurs in the North Caucasus.
Thunderstorms usually last less than an hour. Intense downpours, hailstorms, lightning strikes, gusts of wind, and vertical air currents pose a particular danger. The hail hazard is determined by the size of the hailstones. In the North Caucasus, the mass of hailstones once reached 0.5 kg, and in India, hailstones weighing 7 kg were noted. The most hazardous areas in our country are located in the North Caucasus. In July 1992, hail damaged 18 aircraft at the Mineralnye Vody airport.
Lightning is a hazardous weather phenomenon. They kill people, livestock, cause fires, damage the power grid. About 10,000 people die every year from thunderstorms and their consequences worldwide. Moreover, in some parts of Africa, in France and the United States, the number of victims from lightning is greater than from other natural phenomena. The annual economic damage from thunderstorms in the United States is at least $700 million.
Droughts are typical for desert, steppe and forest-steppe regions. The lack of precipitation causes drying up of the soil, lowering the level of groundwater and in reservoirs until they dry up completely. Moisture deficiency leads to the death of vegetation and crops. Droughts are especially severe in Africa, the Near and Middle East, Central Asia and southern North America.
Droughts change the conditions of human life, have an adverse impact on the natural environment through processes such as salinization of the soil, dry winds, dust storms, soil erosion and forest fires. Fires are especially strong during drought in taiga regions, tropical and subtropical forests and savannahs.
Droughts are short-term processes that last for one season. When droughts last more than two seasons, there is a threat of starvation and mass mortality. Typically, the effect of drought extends to the territory of one or more countries. Especially often prolonged droughts with tragic consequences occur in the Sahel region of Africa.
Atmospheric phenomena such as snowfalls, intermittent heavy rains and prolonged prolonged rains cause great damage. Snowfalls cause massive avalanches in the mountains, and the rapid melting of the fallen snow and prolonged heavy rains lead to floods. A huge mass of water falling on the earth's surface, especially in treeless areas, causes severe erosion of the soil cover. There is an intensive growth of ravine-beam systems. Floods occur as a result of large floods during a period of heavy precipitation or floods after a sudden warming or spring snowmelt and, therefore, are atmospheric phenomena in origin (they are discussed in the chapter on the ecological role of the hydrosphere).
Anthropogenic changes in the atmosphere
Currently, there are many different sources of anthropogenic nature that cause atmospheric pollution and lead to serious violations of the ecological balance. In terms of scale, two sources have the greatest impact on the atmosphere: transport and industry. On average, transport accounts for about 60% of the total amount of atmospheric pollution, industry - 15%, thermal energy - 15%, technologies for the destruction of household and industrial waste - 10%.
Transport, depending on the fuel used and the types of oxidizing agents, emits into the atmosphere nitrogen oxides, sulfur, oxides and dioxides of carbon, lead and its compounds, soot, benzopyrene (a substance from the group of polycyclic aromatic hydrocarbons, which is a strong carcinogen that causes skin cancer).
Industry emits sulfur dioxide, carbon oxides and dioxides, hydrocarbons, ammonia, hydrogen sulfide, sulfuric acid, phenol, chlorine, fluorine and other compounds and chemicals into the atmosphere. But the dominant position among emissions (up to 85%) is occupied by dust.
As a result of pollution, the transparency of the atmosphere changes, aerosols, smog and acid rains appear in it.
Aerosols are dispersed systems consisting of solid particles or liquid droplets suspended in a gaseous medium. The particle size of the dispersed phase is usually 10 -3 -10 -7 cm Depending on the composition of the dispersed phase, aerosols are divided into two groups. One includes aerosols consisting of solid particles dispersed in a gaseous medium, the second - aerosols, which are a mixture of gaseous and liquid phases. The first are called smokes, and the second - fogs. Condensation centers play an important role in the process of their formation. Volcanic ash, cosmic dust, products of industrial emissions, various bacteria, etc. act as condensation nuclei. The number of possible sources of concentration nuclei is constantly growing. So, for example, when dry grass is destroyed by fire on an area of 4000 m 2, an average of 11 * 10 22 aerosol nuclei is formed.
Aerosols began to form from the moment of the emergence of our planet and influenced natural conditions. However, their number and actions, balanced with the general circulation of substances in nature, did not cause deep ecological changes. Anthropogenic factors of their formation shifted this balance towards significant biospheric overloads. This feature has been especially pronounced since mankind began to use specially created aerosols both in the form of toxic substances and for plant protection.
The most dangerous for vegetation cover are aerosols of sulfur dioxide, hydrogen fluoride and nitrogen. When in contact with a wet leaf surface, they form acids that have a detrimental effect on living things. Acid mists, together with the inhaled air, enter the respiratory organs of animals and humans, and aggressively affect the mucous membranes. Some of them decompose living tissue, and radioactive aerosols cause cancer. Among radioactive isotopes, SG 90 is of particular danger not only because of its carcinogenicity, but also as an analogue of calcium, replacing it in the bones of organisms, causing their decomposition.
During nuclear explosions radioactive aerosol clouds form in the atmosphere. Small particles with a radius of 1 - 10 microns fall not only into the upper layers of the troposphere, but also into the stratosphere, in which they are able to stay for a long time. Aerosol clouds are also formed during the operation of reactors of industrial plants that produce nuclear fuel, as well as as a result of accidents at nuclear power plants.
Smog is a mixture of aerosols with liquid and solid dispersed phases that form a foggy curtain over industrial areas and large cities.
There are three types of smog: ice, wet and dry. Ice smog is called Alaskan. This is a combination of gaseous pollutants with the addition of dusty particles and ice crystals that occur when fog droplets and steam from heating systems freeze.
Wet smog, or smog London type sometimes called winter. It is a mixture of gaseous pollutants (mainly sulfur dioxide), dust particles and fog droplets. The meteorological prerequisite for the appearance of winter smog is calm weather, in which a layer of warm air is located above the surface layer of cold air (below 700 m). At the same time, not only horizontal, but also vertical exchange is absent. Pollutants, which are usually dispersed in high layers, in this case accumulate in the surface layer.
Dry smog occurs during the summer and is often referred to as LA-type smog. It is a mixture of ozone, carbon monoxide, nitrogen oxides and acid vapors. Such smog is formed as a result of the decomposition of pollutants by solar radiation, especially its ultraviolet part. The meteorological prerequisite is atmospheric inversion, which is expressed in the appearance of a layer of cold air above the warm one. Gases and solid particles usually lifted by warm air currents are then dispersed in the upper cold layers, but in this case they accumulate in the inversion layer. In the process of photolysis, nitrogen dioxides formed during the combustion of fuel in car engines decompose:
NO 2 → NO + O
Then ozone synthesis occurs:
O + O 2 + M → O 3 + M
NO + O → NO 2
Photodissociation processes are accompanied by a yellow-green glow.
In addition, reactions occur according to the type: SO 3 + H 2 0 -> H 2 SO 4, i.e. strong sulfuric acid is formed.
With change meteorological conditions(appearance of wind or change in humidity) the cold air dissipates and the smog disappears.
The presence of carcinogens in smog leads to respiratory failure, irritation of the mucous membranes, circulatory disorders, asthmatic suffocation, and often death. Smog is especially dangerous for young children.
Acid rain is atmospheric precipitation acidified by industrial emissions of sulfur oxides, nitrogen oxides and vapors of perchloric acid and chlorine dissolved in them. In the process of burning coal and gas, most of the sulfur in it, both in the form of oxide and in compounds with iron, in particular in pyrite, pyrrhotite, chalcopyrite, etc., turns into sulfur oxide, which, together with carbon dioxide, is released into atmosphere. When atmospheric nitrogen and technical emissions are combined with oxygen, various nitrogen oxides are formed, and the volume of nitrogen oxides formed depends on the combustion temperature. The bulk of nitrogen oxides occurs during the operation of vehicles and diesel locomotives, and minority accounted for by energy and industrial enterprises. Sulfur and nitrogen oxides are the main acid formers. When reacting with atmospheric oxygen and the water vapor in it, sulfuric and nitric acids are formed.
It is known that the alkaline-acid balance of the medium is determined by the pH value. Neutral environment has a pH value of 7, acidic is 0, and alkaline is 14. In the modern era, the pH value of rainwater is 5.6, although in the recent past it was neutral. A decrease in pH value by one corresponds to a tenfold increase in acidity and, therefore, at present, rains with increased acidity fall almost everywhere. The maximum acidity of rains recorded in Western Europe was 4-3.5 pH. It should be taken into account that the pH value equal to 4-4.5 is fatal for most fish.
Acid rains have an aggressive effect on the Earth's vegetation cover, on industrial and residential buildings and contribute to a significant acceleration of the weathering of exposed rocks. An increase in acidity prevents the self-regulation of neutralization of soils in which nutrients are dissolved. In turn, this leads to a sharp decrease in yields and causes degradation of the vegetation cover. Soil acidity contributes to the release of those in bound state heavy, which are gradually absorbed by plants, causing them serious tissue damage and penetrating into the human food chain.
A change in the alkaline-acid potential of sea waters, especially in shallow waters, leads to the cessation of the reproduction of many invertebrates, causes the death of fish and disrupts the ecological balance in the oceans.
As a result of acid rain, the forests of Western Europe, the Baltic States, Karelia, the Urals, Siberia and Canada are under the threat of death.
The gaseous envelope that surrounds our planet Earth, known as the atmosphere, consists of five main layers. These layers originate on the surface of the planet, from sea level (sometimes below) and rise to outer space in the following sequence:
- Troposphere;
- Stratosphere;
- Mesosphere;
- Thermosphere;
- Exosphere.
Diagram of the main layers of the Earth's atmosphere
In between each of these main five layers are transitional zones called "pauses" where changes in air temperature, composition and density occur. Together with pauses, the Earth's atmosphere includes a total of 9 layers.
Troposphere: where the weather happens
Of all the layers of the atmosphere, the troposphere is the one with which we are most familiar (whether you realize it or not), since we live at its bottom - the surface of the planet. It envelops the surface of the Earth and extends upwards for several kilometers. The word troposphere means "change of the ball". A very fitting name, as this layer is where our day to day weather happens.
Starting from the surface of the planet, the troposphere rises to a height of 6 to 20 km. The lower third of the layer closest to us contains 50% of all atmospheric gases. It is the only part of the entire composition of the atmosphere that breathes. Due to the fact that the air is heated from below by the earth's surface, which absorbs the thermal energy of the Sun, the temperature and pressure of the troposphere decrease with increasing altitude.
At the top is a thin layer called the tropopause, which is just a buffer between the troposphere and stratosphere.
Stratosphere: home of ozone
The stratosphere is the next layer of the atmosphere. It extends from 6-20 km to 50 km above the earth's surface. This is the layer in which most commercial airliners fly and balloons travel.
Here, the air does not flow up and down, but moves parallel to the surface in very fast air currents. Temperatures increase as you ascend, thanks to an abundance of naturally occurring ozone (O3), a by-product of solar radiation, and oxygen, which has the ability to absorb the sun's harmful ultraviolet rays (any rise in temperature with altitude is known in meteorology as an "inversion") .
Because the stratosphere has warmer temperatures at the bottom and cooler temperatures at the top, convection (vertical movements of air masses) is rare in this part of the atmosphere. In fact, you can view a storm raging in the troposphere from the stratosphere, because the layer acts as a "cap" for convection, through which storm clouds do not penetrate.
The stratosphere is again followed by a buffer layer, this time called the stratopause.
Mesosphere: middle atmosphere
The mesosphere is located approximately 50-80 km from the Earth's surface. The upper mesosphere is the coldest natural place on Earth, where temperatures can drop below -143°C.
Thermosphere: upper atmosphere
The mesosphere and mesopause are followed by the thermosphere, located between 80 and 700 km above the surface of the planet, and containing less than 0.01% of the total air in the atmospheric shell. Temperatures here reach up to +2000° C, but due to the strong rarefaction of the air and the lack of gas molecules to transfer heat, these high temperatures are perceived as very cold.
Exosphere: the boundary of the atmosphere and space
At an altitude of about 700-10,000 km above the earth's surface is the exosphere - the outer edge of the atmosphere, bordering space. Here meteorological satellites revolve around the Earth.
How about the ionosphere?
The ionosphere is not a separate layer, and in fact this term is used to refer to the atmosphere at an altitude of 60 to 1000 km. It includes the uppermost parts of the mesosphere, the entire thermosphere and part of the exosphere. The ionosphere gets its name because it is in this part of the atmosphere that the Sun's radiation is ionized as it passes through magnetic fields Lands on and . This phenomenon is observed from the earth as the northern lights.
The role of the atmosphere in the life of the Earth
The atmosphere is the source of oxygen that people breathe. However, as you ascend to altitude, the total atmospheric pressure drops, resulting in a decrease in partial oxygen pressure.
The human lungs contain approximately three liters of alveolar air. If the atmospheric pressure is normal, then the partial oxygen pressure in the alveolar air will be 11 mm Hg. Art., pressure of carbon dioxide - 40 mm Hg. Art., and water vapor - 47 mm Hg. Art. With an increase in altitude, oxygen pressure decreases, and the pressure of water vapor and carbon dioxide in the lungs in total will remain constant - approximately 87 mm Hg. Art. When the air pressure equals this value, oxygen will stop flowing into the lungs.
Due to the decrease in atmospheric pressure at an altitude of 20 km, water and interstitial body fluid in the human body will boil here. If you do not use a pressurized cabin, at such a height a person will die almost instantly. Therefore, from the point of view physiological features human body, "cosmos" originates from a height of 20 km above sea level.
The role of the atmosphere in the life of the Earth is very great. So, for example, thanks to dense air layers - the troposphere and stratosphere, people are protected from radiation exposure. In space, in rarefied air, at an altitude of over 36 km, ionizing radiation acts. At an altitude of over 40 km - ultraviolet.
When rising above the Earth's surface to a height of over 90-100 km, there will be a gradual weakening, and then the complete disappearance of phenomena familiar to humans, observed in the lower atmospheric layer:
Sound does not propagate.
There is no aerodynamic force and drag.
Heat is not transferred by convection, etc.
The atmospheric layer protects the Earth and all living organisms from cosmic radiation, from meteorites, is responsible for regulating seasonal temperature fluctuations, balancing and equalizing daily ones. In the absence of an atmosphere on Earth, the daily temperature would fluctuate within +/-200С˚. The atmospheric layer is a life-giving "buffer" between the earth's surface and outer space, a carrier of moisture and heat; processes of photosynthesis and energy exchange take place in the atmosphere - the most important biospheric processes.
Layers of the atmosphere in order from the Earth's surface
The atmosphere is a layered structure, which is the following layers of the atmosphere in order from the surface of the Earth:
Troposphere.
Stratosphere.
Mesosphere.
Thermosphere.
Exosphere
Each layer does not have sharp boundaries between them, and their height is affected by latitude and seasons. This layered structure was formed as a result of temperature changes at different heights. It is thanks to the atmosphere that we see twinkling stars.
The structure of the Earth's atmosphere by layers:
What is the earth's atmosphere made of?
Each atmospheric layer differs in temperature, density and composition. The total thickness of the atmosphere is 1.5-2.0 thousand km. What is the earth's atmosphere made of? At present, it is a mixture of gases with various impurities.
Troposphere
The structure of the Earth's atmosphere begins with the troposphere, which is the lower part of the atmosphere about 10-15 km high. This is where most of the atmospheric air is concentrated. Characteristic troposphere - a drop in temperature of 0.6 ˚C as you rise up for every 100 meters. The troposphere has concentrated in itself almost all atmospheric water vapor, and clouds are also formed here.
The height of the troposphere changes daily. In addition, her average value varies with latitude and season. The average height of the troposphere above the poles is 9 km, above the equator - about 17 km. The average annual air temperature over the equator is close to +26 ˚C, and over the North Pole -23 ˚C. The upper line of the boundary of the troposphere above the equator is the average annual temperature of about -70 ˚C, and above north pole in summer -45 ˚C and in winter -65 ˚C. Thus, the higher the altitude, the lower the temperature. The rays of the sun pass freely through the troposphere, heating the surface of the Earth. The heat radiated by the sun is retained by carbon dioxide, methane and water vapor.
Stratosphere
Above the layer of the troposphere is the stratosphere, which is 50-55 km in height. The peculiarity of this layer is the increase in temperature with height. Between the troposphere and stratosphere lies a transitional layer called the tropopause.
Approximately from a height of 25 kilometers, the temperature of the stratospheric layer begins to increase and, upon reaching a maximum height of 50 km, it acquires values from +10 to +30 ˚C.
There is very little water vapor in the stratosphere. Sometimes at an altitude of about 25 km you can find quite thin clouds, which are called "mother-of-pearl". In the daytime, they are not noticeable, but at night they glow due to the illumination of the sun, which is below the horizon. The composition of mother-of-pearl clouds is supercooled water droplets. The stratosphere is made up mostly of ozone.
Mesosphere
The height of the mesosphere layer is approximately 80 km. Here, as it rises upwards, the temperature decreases and at the uppermost boundary it reaches values several tens of C˚ below zero. In the mesosphere, clouds can also be observed, which are presumably formed from ice crystals. These clouds are called "silvery". The mesosphere is characterized by the coldest temperature in the atmosphere: from -2 to -138 ˚C.
Thermosphere
This atmospheric layer got its name from high temperatures. The thermosphere is made up of:
Ionosphere.
exospheres.
The ionosphere is characterized by rarefied air, each centimeter of which at an altitude of 300 km consists of 1 billion atoms and molecules, and at an altitude of 600 km - more than 100 million.
The ionosphere is also characterized by high air ionization. These ions are composed of charged oxygen atoms, charged molecules of nitrogen atoms and free electrons.
Exosphere
From a height of 800-1000 km, the exospheric layer begins. Gas particles, especially light ones, move here at great speed, overcoming the force of gravity. Such particles, due to their rapid movement, fly out of the atmosphere into outer space and disperse. Therefore, the exosphere is called the sphere of scattering. It is predominantly hydrogen atoms that fly into space, which make up the highest layers of the exosphere. Thanks to particles in the upper atmosphere and particles of the solar wind, we can observe the northern lights.
Satellites and geophysical rockets made it possible to establish the presence in the upper atmosphere of the planet's radiation belt, which consists of electrically charged particles - electrons and protons.