Where does the most precipitation fall? Presentation – Where does the most rainfall occur? Highest rainfall for different time periods

04.03.2020

My least favorite autumn phenomenon is rain! Then all the splendor of fading nature is overshadowed by a gray sky, slush, dampness and cold dank wind. It seems that the sky has broken through... My friend, who now lives far from me, in St. Petersburg, laughs at my autumn blues, because in St. Petersburg rains are a common occurrence. Which city in Russia is the rainiest?

Where in Russia does the most rainfall occur?

For some reason, many people believe that the rainiest city is St. Petersburg. But in fact, this opinion is wrong. Yes, there is a lot of precipitation here, but nevertheless, this city is far from being in first place.

The highest precipitation rates are observed in the Far Eastern region. This primarily applies to the Kuril Islands. An absolute record was set in Severo-Kurilsk. Here, about 1840 mm of precipitation usually falls annually. Scientists say that if the water coming from the sky did not evaporate or seep into the ground, but remained on the streets, then this city would quickly turn into a huge swimming pool.

Rating of the rainiest regions of Russia: second place

In second place is the well-known and beloved resort city of Sochi. This city is truly one of the most “wet” cities; about 1,700 mm of various precipitation falls here annually. It is worth noting that summer here is not too humid, and the bulk of precipitation occurs in the cold season - the autumn-winter season. A very unpleasant natural phenomenon is also observed here - tornadoes arising in the sea. They seem to suck water from the sea into themselves, and then, like from a bucket, water the city.

Rating of the rainiest regions of Russia: third place

This place was won by Yuzhno-Kurilsk. Here, 1250 mm is poured onto the ground during the year. Compared to the two previous leaders, it seems that this figure is not so large. But in fact, this is a lot. So, for example, in St. Petersburg - 660 mm per year, which is even less than in Moscow, where 700 mm falls.

The remaining places were distributed as follows:

in fourth place - Petropavlovsk-Kamchatsky;
in fifth place - Yuzhno-Sakhalinsk;
sixth went to Moscow;
seventh - St. Petersburg.

So meteorologists have destroyed the stereotype about the raininess of the Northern capital, which is only at the bottom of the seven rainiest cities!

They are moisture that falls to the surface of the Earth from the atmosphere. They accumulate in clouds, but not all of them allow moisture to fall to the surface of the planet. To do this, it is necessary that drops or crystals be able to overcome air resistance, gaining enough mass for this. This happens due to the connection of droplets with each other.

Precipitation diversity

Depending on what sediments look like and what state of water they are formed from, they are usually divided into six types. Each of them has its own physical characteristics.

Main types:

rain - water drops of 0.5 mm in size;
drizzle - water particles up to 0.5 mm;
snow - hexagonal ice crystals;
snow pellets - round kernels with a diameter of 1 mm or more that can be easily squeezed with your fingers;
ice pellets - rounded nuclei covered with an ice crust that bounce when falling to the surface;
hail - large round ice particles that can sometimes weigh more than 300 g.

Distribution on Earth

There are several types of precipitation depending on the annual cycle. They have their own characteristics.

Equatorial. Even rainfall throughout the year. There are no dry months, the least amount of moisture falls during the equinox and solstices, which occur on 04, 10, 06, 01
Monsoon. Uneven precipitation - the maximum amount falls in the summer season, the minimum in the winter season.
Mediterranean. The maximum precipitation is recorded in winter, the minimum occurs in summer. Found in the subtropics, on the western coasts and in the middle of the continent. There is a gradual decrease in quantity as one approaches the central part of the continent.
Continental. There is more precipitation in the warm season, and with the advent of cold weather it becomes less.
Nautical. Uniform distribution of moisture throughout the year. A slight maximum can be observed in the autumn-winter period.

What affects the distribution of precipitation on Earth

In order to understand where the maximum amount of precipitation occurs on Earth, it is necessary to understand what this indicator depends on.

Precipitation throughout the year is distributed unevenly across the Earth. Their number decreases geographically from the equator to the poles. We can say that their number is influenced by geographic latitude.

Also, their distribution depends on air temperature, movement of air masses, relief, distance from the coast, and sea currents.

For example, if warm, humid ones encounter mountains on their way, they, climbing their slopes, cool and produce precipitation. Therefore, the maximum amount of them falls on mountain slopes, where the wettest areas of the Earth are located.

Where does the maximum rainfall occur?

The equator area is the leader in the amount of precipitation per year. Average figures are 1000-2000 mm of moisture throughout the year. There are areas on certain mountain slopes where this figure increases to 6000-7000. And on the Cameroon volcano (Mongo ma Ndemi) the maximum amount of precipitation falls within 10,000 mm or more.

This is explained by high air temperature, high humidity, and the predominance of rising air currents.

It has long been noted that at a geographic latitude of 20º south and 20º north from the equator, almost 50% of all Earth precipitation falls. Observations over many decades have proven that the maximum amount of precipitation falls at the equator, especially in mountainous areas.

Distribution of the amount of moisture falling to the total amount by continent

After making sure that the maximum amount of precipitation falls on the equator, you can consider the percentage of precipitation by continent.

Maximum annual precipitation

Mount Wamaleale (Hawaii) is considered the rainiest place on the planet. It rains 335 days here throughout the year. The opposite situation can be observed in the Atacama Desert (Chile), where rain may not fall at all during the year.

As for the highest amount of moisture per year on average, the highest figures are in the Hawaiian Islands and India. At Wyville Mountain (Hawaii), the maximum precipitation falls up to 11900 mm, and at Cherrapunji station (India) - up to 11400 mm. These two regions are the richest in falling moisture.

The driest regions are Africa and For example, in the Khara oasis (Egypt) an average of less than 0.1 mm of moisture falls per year, and in the town of Arica (Chile) - 0.5 mm.

Maximum figures in the world

It is already clear that the most moisture occurs at the equator. As for the maximum indicators, they were recorded at different times and on different continents.

Thus, the maximum amount of moisture fell within a minute in the city of Unionville (USA). It happened on 07/04/1956. Their number per minute was 31.2 mm.

If we continue the topic, the maximum daily rainfall was recorded in the city of Silaos in the Indian Ocean). From April 15, 1952 to April 16, 1952, 1870 mm of water fell.

The maximum for the month belongs to the already famous city of Cherrapunji (India), where 9299 mm of rain fell in July 1861. In the same year, the maximum figure was recorded here, which amounted to 26,461 mm per year.

All data presented is not final. Observations of weather conditions show many new records, including those for moisture. Thus, the record for the heaviest rain was broken 14 years later on the island of Guadeloupe. It differed from the previous indicator by several mm.

Where does the most rainfall occur? and got the best answer

Answer from I"ll be better[guru]
In the very center of the island of Kauai in the group of Hawaiian Islands is located, the top of which is one of the rainiest places on the planet. It almost always rains there, and 11.97 meters of precipitation falls per year. This means that if moisture did not flow down, then within a year the mountain would be covered with a layer of water as high as a four-story building. At the very top, almost nothing grows - of all the plants, only algae are adapted to live in such wetness, everything else simply rots there. But around the top there is a riot of greenery.

Waialeale's closest rival in terms of heavenly sluggishness is near the Himalayas, in India. But if on Waialeala it rains all year round, then on Cherrapunji all this burst of precipitation falls in some impossible downpour in three summer months. The rest of the time there... is drought. In addition, no one lives on Waialeala, and Cherrapunji is the rainiest of the populated places.

Warm and moist monsoon flows near Cherrapunji make a sharp rise between the Khasi and Arakan mountains, so the amount of rainfall here increases sharply.

The population of Cherrapunji still remembers 1994, when a record amount of rainfall - 24,555 mm - fell on the tiled roofs of their houses. Needless to say, there was nothing like this in the whole world.
However, do not think that heavy clouds hang over this city all year round. When nature softens a little and the bright sun rises over the surrounding area, a beam of amazingly beautiful rainbow hangs over Cherrapunjee and the surrounding valley.
The rainfall in Cherrapunjee can be rivaled by Quibdo (Columbia): for 7 years, from 1931 to 1937, the average annual rainfall here was 9,564 mm, and in 1936, 19,639 mm of rainfall was recorded. High precipitation is also typical for Debunge (Cameroon), where for 34 years, from 1896 to 1930, an average of 9,498 mm fell, and the maximum amount of precipitation (14,545 mm) was observed in 1919. In Buenaventura and Angote (Colombia) the annual precipitation rate is close to 7,000 mm; in a number of points on the Hawaiian Islands it is within 6,000...9,000 mm.
In Europe, Bergen (Norway) is considered a rather rainy place. However, the Norwegian town of Samnanger receives even more rainfall: over the past 50 years, annual rainfall here has often exceeded 5,000 mm.
In our country, the greatest amount of precipitation falls in Gruzin, in the Chakva region (Adjara) and in Svaneti. In Chakwa, the average annual precipitation is 2,420 mm (extreme values 1,800...3,600 mm).
Source:

Answer from Dudu1953[guru]
In the village of Gadyukino.

Answer from Shvidkoy Yuri[guru]
Cherrapunji (India) - the wettest place on Earth
In terms of annual precipitation, the wettest place in the world is Tutunendo in Colombia - 11,770 mm per year, which is almost 12 meters. On the 5th floor of the Khrushchev five-story building it will be knee-deep.

Answer from Valens[guru]
Probably the rainiest place in the world is Mount Waialeale in Hawaii, on the island of Kauai. The average annual precipitation here is 1197 cm.
Cherrapunjee in India has perhaps the second highest rainfall with an annual average ranging from 1079 to 1143 cm. On one occasion, 381 cm of rain fell in Cherrapunjee in 5 days. And in 1861 the amount of precipitation reached 2300 cm!
To make it more clear, let's compare the amount of precipitation in some cities around the world. London receives 61 cm of rain per year, Edinburgh about 68 cm and Cardiff about 76 cm. New York receives about 101 cm of rain. Ottawa in Canada gets 86 cm, Madrid about 43 cm and Paris 55 cm. So you see how Cherrapunji contrasts.
Some large regions of the Earth experience heavy rainfall all year round. For example, almost every point along the equator receives 152 cm or more of precipitation every year. The equator is the junction point of two large air currents. Everywhere along the equator, air moving down from the north meets air moving up from the south.

Answer from Vadim Bulatov[guru]
Many factors determine how much rain or snow will fall on the earth's surface. These are temperature, altitude, location of mountain ranges, etc.
Probably the rainiest place in the world is Mount Waialeale in Hawaii, on the island of Kauai. The average annual rainfall here is 1197 cm. Cherrapunjee in India has perhaps the second highest rainfall with an average annual rainfall ranging from 1079 to 1143 cm. Once 381 cm of rain fell in Cherrapunjee in 5 days. And in 1861 the amount of precipitation reached 2300 cm!
To make it more clear, let's compare the amount of rainfall in some cities around the world, London receives 61 cm of rain per year, Edinburgh receives about 68 cm, and Cardiff receives about 76 cm. New York receives about 101 cm of rain. Ottawa in Canada gets 86cm, Madrid about 43cm and Paris 55cm. So you see how Cherrapunji contrasts.
The driest place in the world is probably Arica in Chile. Here the precipitation level is 0.05 cm per year.
Some large regions of the Earth experience heavy rainfall all year round. For example, almost every point along the equator receives 152 cm or more of precipitation every year. The equator is the junction point of two large air currents. Everywhere along the equator, air moving down from the north meets air moving up from the south.

There are very rainy places on Earth, and below are unique precipitation records ever recorded by meteorologists. So,

Highest rainfall for different time periods

Highest amount of precipitation per minute

The greatest amount of precipitation that fell in one minute is 31.2 millimeters. This record was recorded by American meteorologists on July 4, 1956 in the vicinity of the city of Unionville.

Maximum amount of precipitation per day

A real global flood occurred on Reunion Island, located in the Indian Ocean. During the day from March 15 to March 16, 1952, 1870 millimeters of precipitation fell there.

Highest rainfall in a month

The record for monthly precipitation is 9299 millimeters. It was observed in the Indian city of Cherrapunji in July 1861.

Most rainfall in a year

Cherrapunji is also the champion for receiving the highest annual rainfall. 26,461 millimeters - this amount fell in this Indian city from August 1860 to July 1861!

Highest and lowest average annual precipitation

The rainiest place on Earth, with the highest average annual precipitation recorded, is Tutunendo in Colombia. The average annual precipitation there is 11,770 millimeters.
The antipode of Tutunendo is the Chilean Atacama Desert. The surrounding area of the city of Kalama, located in this desert, has not been irrigated by rain for more than four hundred years.

On the territory of Russia, with the exception of the large islands of the Arctic Ocean, an average of 9653 km3 of precipitation falls, which could conditionally cover a flat land surface with a layer of 571 mm. Of this amount, 5676 km3 (336 mm) of precipitation is spent on evaporation.

Seasonal and annual precipitation are the average of the monthly totals for the months of the season/year in question. Precipitation time series are presented for the period 1936–2007, during which the main network of meteorological observations in Russia did not change significantly and could not seriously influence the interannual fluctuations of spatially averaged values. All time series show trends (linear trends) of changes for the period 1976–2007, which more than others characterize anthropogenic changes in the modern climate.

Let us note the complex nature of interannual fluctuations in precipitation, especially since the mid-60s. XX century We can distinguish periods of increased precipitation - before the 60s and after the 80s, and between them there are approximately two decades of multidirectional fluctuations.

In general, across the territory of Russia and in its regions (except for the Amur region and Primorye) there is a slight increase in average annual precipitation, most noticeable in Western and Central Siberia. Average annual precipitation trend for 1976-2007. the average for Russia is 0.8 mm/month/10 years and describes 23% of interannual variability.

On average for Russia, the most noticeable feature is the increase in spring precipitation (1.74 mm/month/10 years, contribution to the variance of 27%), apparently due to the Siberian regions and European territory. Another noticeable fact is the decrease in winter and summer precipitation in Eastern Siberia, summer and autumn in the Amur region and Primorye, which, however, did not appear in precipitation trends for Russia as a whole, as it was compensated by an increase in precipitation in Western Siberia.

During the period 1976 – 2007. on the territory of Russia as a whole and in all its regions (except for the Amur region and Primorye), changes in annual precipitation amounts showed a tendency to increase, although these changes were small in magnitude. The most significant seasonal features: an increase in spring precipitation in the Western Siberia region and a decrease in winter precipitation in the Eastern Siberia region.

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Precipitation in Russia

In the formation of annual amounts of atmospheric precipitation, clearly defined patterns are found, characteristic not only for specific territories, but also for the country as a whole. In the direction from west to east, there is a consistent decrease in the amount of atmospheric precipitation, their zonal distribution is observed, which changes under the influence of the terrain and loses its clarity in the east of the country.

In the intra-annual distribution in most parts of the country, there is a predominance of summer precipitation. On an annual basis, the greatest amount of precipitation occurs in June, the least in the second half of winter. The predominance of precipitation during the cold period is typical mainly for the southwestern regions - Rostov, Penza, Samara regions, Stavropol Territory, and the lower reaches of the river. Terek.

In June-August (calendar summer months) more than 30% of the annual precipitation falls on European territory, in Eastern Siberia - 50%, in Transbaikalia and the river basin. Amur – 60–70%. In winter (December-February) 20–25% of precipitation falls in the European part, in Transbaikalia - 5%, in Yakutia - 10%.
The autumn months (September-October) are characterized by a relatively uniform distribution of precipitation throughout the territory (20–30%). In spring (March-May) from the western borders to the river. The Yenisei receives up to 20% of the annual precipitation, east of the river. Yenisei - mainly 15–20%. The least amount of precipitation at this time is observed in Transbaikalia (about 10%).
The most general idea of the nature of changes in atmospheric precipitation on the territory of the Russian Federation in the second half of the 20th and early 21st centuries is provided by time series of spatially averaged average annual and seasonal anomalies of atmospheric precipitation.

In the same climatic zone, the influence of groundwater on forest productivity, especially the depth of its occurrence, can be different depending on the composition of plantings, topography, soil, its physical properties, etc.

Snowfall in Russia. Photo: Peter

Of decisive importance for forestry and agriculture is not the total annual amount of precipitation, but its distribution by season, month, decade, and the nature of the precipitation itself.
Over the vast territory of Russia, precipitation falls mainly in the summer. Precipitation in the form of snow in the north (Arkhangelsk region) is about 1/3, and in the south (Kherson) it is about 10% of the total annual precipitation.

According to the degree of moisture supply, it is customary to divide the territory of Russia into the following zones: excessive, unstable and insufficient moisture. These zones coincide with the vegetation zones - taiga, forest-steppe and steppe. In forestry, the area of insufficient moisture is usually called the area of dry forestry. It includes the Kuibyshev, Orenburg, Saratov and Vologda regions, as well as some regions of Ukraine, the Altai Territory, and the Central Asian republics. In the forest-steppe zone, moisture is a decisive factor for the success of reforestation.

Lack of moisture, especially during the growing season, leaves a deep imprint on all vegetation and, in particular, on forest vegetation.
Thus, in Georgia, in the Borjomi region, beech, pine and spruce forests and luxurious tall-grass subalpine meadows are common due to the humid climate. The Tskhra-Tskharo mountain range sharply delimits this area, and on the other side there are treeless spaces due to low rainfall and summer droughts (P. M. Zhukovsky).
In the European part of Russia, precipitation gradually decreases from the western borders to the Middle and Lower Volga.

As a result, in the west, a vast area is covered by various forests and large forest swamps, and in the southeast there is a steppe, turning into a desert. Therefore, the sum of annual precipitation without data on the frequency of its occurrence, especially during the growing season, without taking into account soil and other natural conditions, the requirements of species for moisture, and the number of trees per unit area is an indicator of little value for determining the humidity regime, for the appearance of a forest, its growth and development .
Even in the same area with the same type of lack of precipitation, for example, in the forest-steppe on the sandy soils of the dune hills of the Buzuluksky forest, plantings may suffer from a lack of moisture, but on sandy soils of a flat topography they may not experience a lack of moisture.
Long summer dry periods contribute to changes in the soil cover of the forest, causing the falling of leaves, fruits, and drying out of trees in the forest. After prolonged droughts, the death of trees can continue for several subsequent years and affect the structure of tree stands and the relationships of species.

The driest places in Russia are the intermountain basins of Altai (Chuya steppe) and Sayan (Ubsunur basin). The annual precipitation here barely exceeds 100 mm. Humid air does not reach the interior of the mountains. Moreover, descending along the slopes into basins, the air heats up and dries out even more.
Please note that places with both minimum and maximum precipitation are located in the mountains. In this case, the maximum amount of precipitation falls on the windward slopes of mountain systems, and the minimum - in intermountain basins.

Humidity coefficient. 300 mm of precipitation - is it a lot or a little? This question cannot be answered unequivocally. This amount of precipitation is typical, for example, for both the northern and southern parts of the West Siberian Plain. At the same time, in the north the territory is clearly waterlogged, as evidenced by severe swampiness; and in the south, dry steppes are widespread - a manifestation of moisture deficiency. Thus, with the same amount of precipitation, the moisture conditions turn out to be fundamentally different.
In order to assess whether the climate in a given place is dry or humid, it is necessary to take into account not only the annual amount of precipitation, but also evaporation.

Where in Russia does the least and where does the greatest amount of precipitation occur? How much and why?

On the territory of Russia, with the exception of the large islands of the Arctic Ocean, an average of 9653 km3 of precipitation falls, which could conditionally cover a flat land surface with a layer of 571 mm.
Of this amount, 5676 km3 (336 mm) of precipitation is spent on evaporation.
In the formation of annual amounts of atmospheric precipitation, clearly defined patterns are found, characteristic not only for specific territories, but also for the country as a whole (Fig. 1.4). In the direction from west to east, there is a consistent decrease in the amount of atmospheric precipitation, their zonal distribution is observed, which changes under the influence of the terrain and loses its clarity in the east of the country.
In the intra-annual distribution in most parts of the country, there is a predominance of summer precipitation. On an annual basis, the greatest amount of precipitation occurs in June, the least in the second half of winter. The predominance of precipitation during the cold period is typical mainly for the southwestern regions of the Rostov, Penza, Samara regions, Stavropol Territory, and the lower reaches of the river. Terek.
In June-August (calendar summer months) more than 30% of the annual precipitation falls on European territory, in Eastern Siberia 50%, in Transbaikalia and the river basin. Amur 6070%. In winter (December-February) 20-25% of precipitation falls in the European part, 5% in Transbaikalia, 10% in Yakutia.
The autumn months (September-October) are characterized by a relatively uniform distribution of precipitation throughout the territory (20-30%). In spring (March-May) from the western borders to the river. The Yenisei receives up to 20% of the annual precipitation, east of the river. Yenisei is mainly 1520%. The least amount of precipitation at this time is observed in Transbaikalia (about 10%).
The most general idea of the nature of changes in atmospheric precipitation on the territory of the Russian Federation in the second half of the 20th and early 21st centuries is provided by time series of spatially averaged average annual and seasonal anomalies of atmospheric precipitation.

Attention, TODAY only!

1. Climate formation factors.

2. Climatic conditions of the seasons of the year. The ratio of heat and moisture.

3. Climatic zones and regions.

Climate formation factors

The climate of Russia, like that of any region, is formed under the influence of a number of climate-forming factors. The main climate-forming factors are: solar radiation (geographic latitude), circulation of air masses, proximity to the oceans, relief, underlying surface, etc.

Solar radiation is the basis for the transfer of heat to the earth's surface. The further from the equator, the smaller the angle of incidence of the sun's rays, the correspondingly less solar radiation. The amount of solar radiation reaching the surface and its intra-annual distribution are determined by the latitudinal position of the country. Russia is located between 77° and 41° N, and its main part is between 70° and 50° N. The large extent of the territory from north to south determines significant differences in the annual total radiation between the north and south of the country. The lowest annual total radiation is typical for the polar islands of the Arctic and the Varangerfjord region (there is also a lot of cloudiness here). The highest annual total solar radiation becomes in the south, on the Taman Peninsula, in Crimea and in the Caspian region. In general, the annual total radiation increases approximately twofold from north to south of Russia.

Atmospheric circulation processes are of great importance in providing heat resources. Circulation occurs under the influence of pressure centers that change with the seasons, which, of course, affects the prevailing winds. However, in most of Russia, westerly winds are predominant, with which the bulk of precipitation is associated. Russia is characterized by three types of air masses: 1) moderate; 2) arctic; 3) tropical. All of them are divided into two subtypes: marine and continental. These differences are especially noticeable for temperate and tropical air masses. Moderate air masses dominate over most of Russia all year round. Continental temperate masses form directly over the territory of Russia.

This air is dry, cold in winter and very warm in summer. Temperate sea air comes from the North Atlantic, and to the eastern regions of the country it comes from the Pacific Ocean. This air is humid, warm in winter and cool in summer. When moving from west to east, sea air transforms and acquires the features of continental air.

The climatic features of the southern half of Russia are sometimes influenced by tropical air. Local continental tropical air is formed over Central Asia and southern Kazakhstan, as well as during the transformation of air of temperate latitudes over the Caspian region and Transcaucasia. This air is very dry, very dusty and has high temperatures. Marine tropical air penetrates from the Mediterranean (to the European part of Russia and the Caucasus) and from the central regions of the Pacific Ocean (to the southern regions of the Far East). It is humid and relatively warm.

Arctic air forms over the Arctic Ocean and often affects the northern half of Russia, especially Siberia. This air is dry, very cold and transparent. The air that forms over the Barents Sea (marine arctic air) is less cold and more humid.

When different air masses come into contact, atmospheric fronts arise, the climate-forming significance of which is increased cloudiness, precipitation and increased wind. All year round, the territory of Russia is subject to the influence of cyclones and anticyclones, which determine weather conditions. The climate of Russia is influenced by the following pressure centers: Icelandic and Aleutian minima; Azores and Arctic highs; Asian maximum (winter only).

Affects climate and distance from oceans; because Since western winds dominate most of the territory of Russia, the Atlantic Ocean has the main influence on the country's climate. Its impact is felt all the way to Lake Baikal and Taimyr. As you move eastward from Russia's western borders, winter temperatures quickly drop and the amount of precipitation generally decreases. The influence of the Pacific Ocean is felt mainly in the coastal zone of the Far East, which is greatly facilitated by the relief.

Relief has a significant impact on climate. The distribution of mountains in the east and south of Siberia, openness to the north and west, ensures the influence of the North Atlantic and the Arctic Ocean on most of the territory of Russia. The influence of the Pacific Ocean is screened (blocked) by orographic barriers. The climatic conditions on the plains and in the mountainous regions differ markedly. In the mountains, the climate changes with altitude. Mountains “aggravate” cyclones. Differences are observed on windward and leeward slopes, as well as intermountain basins.

Affects the climate and the nature of the underlying surface. Thus, the snow surface reflects up to 80-95% of solar radiation. Vegetation, as well as soils, their color, humidity, etc., also have different reflectivity. Forests, especially conifers, weakly reflect the sun's rays (about 15%). Moist, freshly plowed chernozem soil has the lowest albedo (less than 10%).

Climatic conditions of the seasons of the year.

Heat and moisture ratio

Climatic conditions in winter

In winter, the radiation balance throughout the country is negative. The highest values of total solar radiation are observed in winter in the south of the Far East, as well as in the south of Transbaikalia. To the north, radiation decreases rapidly due to the lower position of the Sun and the shortening of the day. North of the Arctic Circle, the polar night sets in (at a latitude of 70°, the polar night lasts about 53 days). The Asian High is formed over southern Siberia and northern Mongolia, from which two spurs extend: to the northeast to Oymyakon; the other - west to the Azores High - Voeikov axis. This axis plays an important role as a climate divide. To the south of it (the south of the Russian Plain and Ciscaucasia) cold northeastern and eastern winds blow. West and southwest winds blow north of the axis. The western transport is also enhanced by the Icelandic low, the trough of which reaches the Kara Sea. These winds bring in relatively warm and humid air from the Atlantic. Over the territory of the northeast, under the conditions of a basin topography and a minimum of solar radiation, very cold arctic air is formed in winter. Off the coast of Kamchatka there is the Aleutian Low, where the pressure is low. Here, on the eastern edge of Russia, an area of low pressure is located in close proximity to the northeastern spur of the Asian High, therefore a high pressure gradient is formed and cold winds from the continent rush to the shores of the Pacific Ocean (winter monsoon).

January isotherms over the territory of Russia are submeridional. The -4°С isotherm passes through the Kaliningrad region. Near the western borders of the compact territory of Russia there is an isotherm of -8°C; to the south it deviates east of Astrakhan. An isotherm of -12°C passes through the Nizhny Novgorod region, and -20°C beyond the Urals. Over Central Siberia the isotherms are -30°С and -40°С, in the basins of North-East Siberia the isotherm is -48°С (the absolute minimum is -71°С). In Ciscaucasia, isotherms bend and average temperatures vary from -5°C to -2°C. It is warmer than expected in winter on the Kola Peninsula - about -8°C, which is facilitated by the warm North Cape Current. In the Far East, the course of isotherms follows the contours of the coasts. The isotherm runs along the Kuril ridge -4°С, along the eastern coast of Kamchatka -8°С, and along the western coast -20°С; in Primorye -12°C. The greatest amount of precipitation falls in Kamchatka and the Kuril Islands; it is brought by cyclones from the Pacific Ocean. In most parts of Russia in winter, precipitation comes from the Atlantic Ocean, and accordingly, the amount of precipitation generally decreases from west to east. But there is also a lot of precipitation on the southwestern slopes of the Caucasus, thanks to Mediterranean cyclones. Winter precipitation in Russia falls almost everywhere, mainly in solid form, and snow cover forms everywhere. The shortest duration of its occurrence is on the plains in the Ciscaucasia (just over a month), and in the south of Primorye - more than three months. Further to the north and east, the duration of snow cover increases and reaches a maximum in Taimyr - about 9 months a year. And only on the Black Sea coast of the Caucasus does a stable snow cover form. The lowest depth of snow cover in the Caspian region is about 10 cm. In the Kaliningrad region, in the south of the Russian Plain, in Transbaikalia - about 20 cm. In most of the country, the snow height ranges from 40 cm to 1 meter. And its greatest height is observed in Kamchatka - up to 3 meters.

Climatic conditions in summer

In summer, the role of solar radiation increases sharply. Radiation reaches its highest values in the Caspian region and on the Black Sea coast of the Caucasus. To the north, the amount of solar radiation decreases slightly, as the length of the day increases to the north. It's a polar day in the Arctic. In summer, the radiation balance throughout the country is positive.

July isotherms are sublatitudinal. On the northernmost islands the temperature is close to zero, on the coast of the Arctic seas + 4° +8°С, near the Arctic Circle the air temperature already reaches +10° +13°С. To the south the temperature rise is more gradual. The average July temperature reaches its maximum value in the Caspian region and Eastern Ciscaucasia: + 25°C.

In summer, the land warms up over southern Siberia, and atmospheric pressure decreases. In this regard, Arctic air rushes deep into the continent, while it transforms (warms up). From the Hawaiian High, air flows toward the Far East, creating the summer monsoon. The spur of the Azores High enters the Russian Plain, while the western transport is preserved. In summer, almost the entire territory of Russia receives maximum precipitation. In general, the amount of precipitation in summer decreases from west to east, from 500 mm in the Kaliningrad region to 200 mm in Central Yakutia. In the Far East, their number increases again, in Primorye - up to 800 mm. A lot of precipitation falls on the slopes of the Western Caucasus - up to 1500 mm, the minimum falls on the Caspian lowland - 150 mm.

The amplitude of average monthly temperatures in January and July increases from the west from the Baltic to the east to the Pacific Ocean. Thus, in the Kaliningrad region the amplitude is 21°C, in the Nizhny Novgorod Right Bank 31°C, in Western Siberia 40°C, in Yakutia 60°C. Moreover, the increase in amplitude is mainly due to the increasing severity of winters. In Primorye, the amplitude begins to decrease again - to 40°C, and in Kamchatka - to 20°C.

Annual precipitation varies sharply between the plains and the mountains. On the plains, the greatest amount of precipitation falls in the 55°N latitude band. – 65°N, here the decrease in precipitation goes from 900 mm in the Kaliningrad region to 300 mm in Yakutia. In the Far East, an increase in precipitation is again observed up to 1200 mm, and in the southeast of Kamchatka - up to 2500 mm. At the same time, on elevated parts of the relief, an increase in precipitation occurs almost everywhere. To the north and south of the central zone, the amount of precipitation decreases: in the Caspian region and the tundra of North-East Siberia to 250 mm. In the mountains, on windward slopes, the annual amount of precipitation increases to 1000 - 2000 mm, and its maximum is observed in the southwest of the Greater Caucasus - up to 3700 mm.

The provision of moisture to an area depends not only on precipitation, but also on evaporation. It increases from north to south following an increase in solar radiation. The ratio of heat and moisture is an important climatic indicator; it is expressed by the humidification coefficient (the ratio of annual precipitation to evaporation). The optimal ratio of heat and moisture is observed in the forest-steppe zone. To the south, moisture deficit increases and moisture becomes insufficient. In the north of the country there is excessive moisture.

Climatic zones and regions

Russia is located in three climatic zones: arctic, subarctic and temperate. The belts differ from each other in their radiation regime and prevailing air masses. Within the zones, climatic regions are formed that differ from each other in the ratio of heat and moisture, the sum of temperatures during the active growing season, and precipitation patterns.

The Arctic belt covers almost all the islands of the Arctic Ocean and the northern coast of Siberia. Arctic air masses dominate here all year round. In winter there is a polar night and there is no solar radiation. Average temperatures in January vary from -20°C in the west to -38°C in the east; in July, temperatures vary from 0°C on the islands to +5°C on the Siberian coast. Precipitation ranges from 300 mm in the west to 200 mm in the east, and only on Novaya Zemlya, in the Byrranga mountains and on the Chukotka Plateau, up to 500 mm. Precipitation falls mainly in the form of snow, and in summer sometimes in the form of drizzle.

The subarctic belt is located south of the Arctic, it runs along the north of the East European and West Siberian plains, without going beyond the southern borders of the Arctic Circle. In Eastern Siberia, the subarctic belt extends much further to the south – up to 60°N. In winter, arctic air dominates in this zone, and in summer it is temperate. In the west, on the Kola Peninsula, the climate is subarctic maritime. Average temperatures in winter are only -7°C -12°C, and in summer +5°C +10°C. Precipitation falls up to 600 mm per year. To the east, the climate becomes more continental. In the basins of North-Eastern Siberia, the average January temperature drops to -48°C, but towards the Pacific coast it becomes more than 2 times warmer. Summer temperatures vary from +5°C on Novaya Zemlya to +14°C near the southern border of the belt. Precipitation amounts to 400-450 mm, but in mountainous areas their amount can increase to 800 mm.

The temperate zone covers the rest, most of the country. Moderate air masses prevail here all year round. The temperate zone has well-defined seasons. Within this belt, there are significant differences in the ratio of heat and moisture - both from north to south and from west to east. The change in climatic features from north to south is associated with radiation conditions, and from west to east – with circulation processes. Within the temperate zone, there are 4 climatic regions, in which 4 types of climate are respectively formed: temperate continental, continental, sharply continental, monsoon.

A temperate continental climate is typical for the European part of Russia and the Urals. The Atlantic air often dominates here, so winters are not harsh, and there are often thaws. The average January temperature varies from -4°C in the west to -25°C in the east, and the average July temperature ranges from +13°C in the north to +24°C in the south. Precipitation ranges from 800-850 mm in the west to 500-400 mm in the east. Most of the precipitation occurs during the warm period.

Continental climate is typical for Western Siberia and the Caspian region. Continental air of temperate latitudes predominates here. The air coming from the Atlantic, passing over the Russian Plain, is transformed. The average winter temperature in Western Siberia is -20°C -28°C, in the Caspian region - about -6°C. In summer in Western Siberia it varies from +15°C in the north to +21°C in the south, in the Caspian region – up to +25°C. Precipitation amounts to 400-500 mm, in the Caspian region no more than 300 mm.

A sharply continental climate is characteristic of the temperate zone of Central Siberia and Transbaikalia. Continental air of temperate latitudes dominates here all year round. Average temperatures in winter are -30°C -45°C, and in summer +15°C +22°C. Precipitation is 350-400 mm.

Monsoon climate is typical for the eastern outskirts of Russia. In winter, cold, dry air from temperate latitudes dominates here, and in summer, humid air comes from the Pacific Ocean. Average temperatures in winter vary from -15°C on the islands to -30°C on the mainland of the region. Average temperatures in summer vary from +12°C in the north to +20°C in the south. Precipitation falls up to 1000 mm (2 times more in Kamchatka), all precipitation occurs mainly in the warm period of the year.

In mountainous areas, special mountain types of climate are formed. In the mountains, solar radiation increases, but the temperature drops with altitude. Mountain regions are characterized by temperature inversions, as well as mountain-valley winds. In the mountains there is more precipitation, especially on windward slopes.

Nature of Russia

Geography textbook for 8th grade

§ 10. Types of climates in Russia

Patterns of heat and moisture distribution in our country. The huge extent of the territory of our country and its location in several climatic zones lead to the fact that in different parts of the country the temperatures in January and July and the annual amount of precipitation differ greatly.

Rice. 35. Average January temperatures

Thus, average January temperatures are 0...-5°C in the far west of the European part (Kaliningrad) and in the Ciscaucasia and -40...-50°C in Yakutia. July temperatures range from -1°C on the northern coast of Siberia to +24...+25°C in the Caspian lowland.

Using Figure 35, determine where in our country the areas with the lowest and highest January temperatures are located. Find the coldest areas and explain why they are located there.

Let's analyze the maps of average isotherms in January and July in Russia. Pay attention to how they pass. January isotherms are located not in a latitudinal direction, but from northwest to southeast. July isotherms, on the contrary, are close to the latitudinal direction.

How can we explain this picture? It is known that the temperature distribution depends on the underlying surface, the amount of solar radiation, and atmospheric circulation. Intensive cooling of the surface of our country in winter leads to the fact that the lowest winter temperatures are observed in internal areas inaccessible to the warming influence of the Atlantic and in areas of Central and North-Eastern Siberia.

Average monthly temperatures in July are positive throughout Russia.

Summer temperatures are of great importance for the development of plants, for soil formation, and for types of agriculture.

Using Figure 36, determine how the July isotherm of +10°C passes. By comparing the physical and climatic maps, explain the reason for the deviation of the isotherm to the south in a number of regions of the country. What is the July isotherm in the southern temperate region? What are the reasons for the closed position of isotherms in the south of Siberia and the north of the Far East?

Rice. 36. Average July temperatures

Distribution of precipitation in our country associated with the circulation of air masses, relief features, as well as air temperature. An analysis of a map showing the annual distribution of precipitation fully confirms this. The main source of moisture for our country is the humid air of the Atlantic. The greatest amount of precipitation on the plains falls between 55° and 65° N. w.

The amount of precipitation is extremely unevenly distributed throughout the territory of our country. The decisive factors in this case are proximity or distance from the sea, the absolute height of the place, the location of mountain ranges (retaining moist air masses or not preventing their movement).

Rice. 37. Annual precipitation

The greatest amount of precipitation in Russia falls in the Caucasus and Altai mountains (more than 2000 mm per year), in the south of the Far East (up to 1000 mm), as well as in the forest zone of the East European Plain (up to 700 mm). The minimum amount of precipitation occurs in the semi-desert areas of the Caspian lowland (about 150 mm per year).

On the map (Fig. 37) trace how within the band 55-65° N. w. The annual amount of precipitation changes when moving from west to east. Compare the map of precipitation distribution over the territory of Russia with a physical map and explain why the amount of precipitation decreases as you move east, why the western slopes of the Caucasus, Altai, and Urals receive the greatest amount of precipitation.

But the annual amount of precipitation does not yet give a complete picture of how the territory is provided with moisture, since some of the precipitation evaporates and some seeps into the soil.

To characterize the provision of a territory with moisture, the humidification coefficient (K) is used, showing the ratio of the annual amount of precipitation to evaporation for the same period: K = O/I.

Volatility is the amount of moisture that can evaporate from a surface under given atmospheric conditions. The evaporation rate is measured in mm of the water layer.

Volatility characterizes possible evaporation. Actual evaporation cannot exceed the annual amount of precipitation falling in a given location. For example, in the Caspian deserts, evaporation is 300 mm per year, although evaporation here, in hot summer conditions, is 3-4 times higher.

The lower the humidification coefficient, the drier the climate. When the humidification coefficient is equal to one, the humidification is considered sufficient. Sufficient moisture is typical for the southern border of the forest and northern border of the forest-steppe zone.

In the steppe zone, where the moisture coefficient is less than one (0.6-0.7), moisture is considered insufficient. In the Caspian region, in the zone of semi-deserts and deserts, where K = 0.3, moisture is poor.

But in some areas of the country K > 1, that is, the amount of precipitation exceeds evaporation. This type of moisture is called excess moisture. Excessive moisture is typical for taiga, tundra, and forest-tundra. There are many rivers, lakes, and swamps in these areas. Here, water erosion plays a significant role in the processes of relief formation. In areas with insufficient moisture, rivers and lakes are shallow, often dry out in summer, vegetation is sparse, and wind erosion predominates in relief formation.

Rice. 38. Evaporation and volatility

Using the map (Fig. 38), determine in which areas of your country evaporation is minimal and in which it is maximum. Write down these numbers in your notebooks.

Types of climates in Russia. Different types of climates are formed on the territory of Russia. Each of them is characterized by the most common features such as temperature, precipitation, and prevailing weather types by season. Within the same type of climate, the quantitative indicators of each element can vary significantly, which makes it possible to distinguish climatic regions. Zonal changes (differences) are especially great in the largest climatic zone of Russia - the temperate one: from the taiga climate to the desert climate, from the maritime climate of the coasts to the sharply continental climate within the continent at the same latitude.

Using the maps, determine in which climatic zone the main part of the territory of Russia is located, which climatic zones occupy the smallest area in our country.

Arctic climate characteristic of the islands of the Arctic Ocean and its Siberian coasts, where zones of arctic deserts and tundras are located. Here the surface receives very little solar heat. Cold arctic air prevails throughout the year. The severity of the climate increases due to the long polar night, when solar radiation does not reach the surface. Anticyclones dominate, which lengthens the winter and shortens the remaining seasons of the year to 1.5-2 months. This climate has almost two seasons: a long, cold winter and a short, cool summer. The passage of cyclones is associated with weakening frosts and snowfalls. Average temperatures in January are -24…-30°C. Summer temperatures are low: +2…+5°С. Precipitation is limited to 200-300 mm per year. They fall mainly in winter in the form of snow.

Subarctic climate typical for territories located beyond the Arctic Circle on the Russian and West Siberian Plains. In areas of Eastern Siberia, this type of climate is common up to 60° N. w. Winters are long and harsh, and the severity of the climate increases as you move from west to east. Summer is warmer than in the Arctic zone, but short and rather cold (average July temperatures range from +4 to +12°C).

The annual precipitation is 200-400 mm, but due to low evaporation values, constant excess moisture is created. The influence of Atlantic air masses leads to the fact that in the tundra of the Kola Peninsula, compared to the mainland, the amount of precipitation increases and winter temperatures are higher than in the Asian part.

Temperate climate. The temperate climate zone is the largest climate zone in Russia by area; therefore, it is characterized by very significant differences in temperature conditions and moisture as one moves from west to east and from north to south. Common to the entire belt are clearly defined four seasons of the year - winter, spring, summer, autumn.

Moderate continental climate dominates in the European part of Russia. The main features of this climate: warm summers (July temperature +12...+24°C), frosty winters (average January temperatures from -4 to -20°C), annual precipitation of more than 800 mm in the west and up to 500 mm in the center of Russian plains. This climate is formed under the influence of the westerly transfer of Atlantic air masses, relatively warm in winter and cool in summer, constantly humid. In the region of a temperate continental climate, moisture varies from excessive in the north and northwest to insufficient in the east and southeast. This is reflected in the change of natural zones from taiga to steppe.

Continental climate The temperate zone is typical for Western Siberia. This climate is formed under the influence of continental air masses of temperate latitudes, most often moving in the latitudinal direction. Cold arctic air moves in a meridional direction to the south, and continental tropical air penetrates far to the north of the forest belt. Therefore, precipitation here is 600 mm per year in the north and less than 200 mm in the south. Summer is warm, even sultry in the south (average July temperatures range from +15 to +26°C). Winter is harsh compared to the temperate continental climate - average January temperatures are -15...-25°C.

Alexander Ivanovich Voeikov (1842-1916)

Alexander Ivanovich Voeikov is a famous Russian climatologist and geographer. He is considered the founder of climatology in Russia. A.I. Voeikov was the first to establish the dependence of various climatic phenomena on the ratio and distribution of heat and moisture, revealing the features of the general circulation of the atmosphere. The main, classic work of the scientist is “Climates of the Globe, Especially Russia.” Traveling a lot to different countries, A.I. Voeikov studied the climate and vegetation everywhere.

The scientist paid special attention to studying the influence of climate on agricultural crops. In addition, A.I. Voeikov studied population geography, complex regional studies and other problems. Deeply for his time, A.I. Voeikov studied various types of human influence on nature, pointed out some unfavorable aspects of this influence and proposed correct methods of transforming it, based on the known laws of the development of nature.

The change in natural zones is clearly evident when moving from north to south from the taiga to the steppes.

Sharply continental climate temperate zone is common in Eastern Siberia. This climate is characterized by the constant dominance of continental air of temperate latitudes. The sharply continental climate is characterized by low cloudiness and scanty precipitation, the bulk of which falls in the warm part of the year. Light clouds contribute to the rapid heating of the earth's surface by the sun's rays during the day and summer and, conversely, its rapid cooling at night and in winter. Hence the large amplitudes (differences) in air temperatures, warm and hot summers and frosty winters with little snow. Little snow and severe frosts (average January temperature -25...-45°C) ensure deep freezing of soils and soils, and this, in temperate latitudes, causes the accumulation and preservation of permafrost. Summer is sunny and warm (average July temperatures range from +16 to +20°C). Annual precipitation is less than 500 mm. The humidification coefficient is close to unity. Within this climate is the taiga zone.

Monsoon climate temperate zone is typical for the southern regions of the Far East. Typically, when the continent cools in winter and the resulting increase in atmospheric pressure, dry and cold air rushes towards the warmer air over the ocean. In summer, the continent warms up more than the ocean, and now colder oceanic air rushes to the continent, bringing cloudiness and heavy precipitation; sometimes typhoons even form. Average January temperatures here are -15…-30°C; in summer, in July, +10…+20°С. Precipitation - 600-800 mm per year - falls mainly in summer. If the melting of snow in the mountains coincides with heavy rainfall, floods occur. Humidification is excessive everywhere (humidification coefficient is greater than one).

Questions and tasks

What patterns in the distribution of heat and moisture can be established by analyzing maps (see Fig. 31, 38)?
How is the moisture coefficient determined and why is this indicator so important?
In which regions of Russia is the coefficient greater than one, in which is it less? How does this affect other components of nature?
Name the main types of climate in Russia.
Explain why the greatest differences in climatic conditions are observed within the temperate zone as you move from west to east.
Name the main features of continental climate and indicate how this climate affects other components of nature.