In the oceans and seas, huge streams of water tens and hundreds of kilometers wide and several hundred meters deep move in certain directions over distances of thousands of kilometers. Such flows - "in the oceans" - are called sea currents. They move at a speed of 1-3 km/h, sometimes up to 9 km/h. There are several reasons that cause currents: for example, heating and cooling of the water surface, and evaporation, differences in water density, but the most significant role in the formation of currents is.
Currents, according to their prevailing direction, are divided into those going to the west and east, and meridional - carrying their waters to the north or south.
A separate group includes currents that move towards neighboring ones, which are more powerful and extended. Such flows are called countercurrents. Those currents that change their strength from season to season depending on the direction of coastal winds are called monsoon currents.
Among the meridional currents, the Gulf Stream is the most famous. It transports on average about 75 million tons of water every second. For comparison, we can point out that the deepest one carries only 220 thousand tons of water every second. The Gulf Stream transports tropical waters to temperate latitudes, largely determining the life of Europe. It was thanks to this current that it received a mild, warm climate and became the promised land for civilization, despite its northern position. Approaching Europe, the Gulf Stream is no longer the same stream that breaks out of the Gulf. Therefore, the northern continuation of the current is called. Blue waters are replaced by more and more green ones. Of the zonal currents, the most powerful is the current of the Western winds. In the vast expanse of the Southern Hemisphere there are no significant land masses off the coast. Strong and steady westerly winds prevail over this entire area. They intensively transport ocean waters in an easterly direction, creating the most powerful current of the Western winds throughout. It connects the waters of three oceans in its circular flow and transports about 200 million tons of water every second (almost 3 times more than the Gulf Stream). The speed of this current is low: to bypass Antarctica, its waters need 16 years. The width of the flow of the Western winds is about 1300 km.
Depending on the water, currents can be warm, cold or neutral. The water of the former is warmer than the water in the region of the ocean through which they pass; the latter, on the contrary, are colder than the water surrounding them; still others do not differ from the temperature of the waters through which they flow. As a rule, currents moving away from the equator are warm; the currents flowing are cold. They are usually less salty than warm. This is because they flow from areas with more precipitation and less evaporation, or from areas where the water is desalinated by melting ice. Cold currents in parts of the oceans are formed due to the rise of cold deep waters.
An important regularity of currents in the open ocean is that their direction does not coincide with the direction of the wind. It deviates to the right in the Northern Hemisphere and to the left in the Southern Hemisphere from the wind direction by an angle of up to 45°. Observations show that in real conditions the deviation at all latitudes is slightly less than 45°. Each underlying layer continues to deviate to the right (left) from the direction of movement of the overlying layer. At the same time, the flow speed decreases. Numerous measurements have shown that the currents end at depths not exceeding 300 meters. The significance of ocean currents lies primarily in the redistribution of solar heat on Earth: warm currents contribute to an increase in temperature, and cold currents lower it. Currents have a huge impact on the distribution of precipitation on land. Territories washed by warm waters always have a humid climate, and cold ones always have a dry climate; in the latter case, rains do not fall; they only have a moisturizing value. Living organisms are also transported with currents. This primarily applies to plankton, followed by large animals. When warm currents meet cold ones, upward currents of water are formed. They raise deep water rich in nutritious salts. This water favors the development of plankton, fish and marine animals. Such places are important fishing grounds.
The study of sea currents is carried out both in the coastal zones of the seas and oceans, and in the open sea by special sea expeditions.
Oceanic or sea currents - this is the forward movement of water masses in the oceans and seas, caused by various forces. Although the most significant cause of currents is wind, they can also form because of unequal salinity of individual parts of the ocean or sea, differences in water levels, uneven heating of different areas of water areas. In the depths of the ocean there are vortices created by bottom irregularities; their size often reaches 100-300 km in diameter, they capture layers of water hundreds of meters thick.
If the factors causing currents are constant, then a constant current is formed, and if they are episodic in nature, then a short-term, random current is formed. According to the predominant direction, currents are divided into meridional, carrying their waters to the north or south, and zonal, spreading latitudinally. Currents in which the water temperature is higher than the average temperature for
the same latitudes are called warm, lower ones are called cold, and currents that have the same temperature as the surrounding waters are called neutral.
Monsoon currents change direction from season to season, depending on how the offshore monsoon winds blow. Countercurrents move towards neighboring, more powerful and extended currents in the ocean.
The direction of currents in the World Ocean is influenced by the deflecting force caused by the rotation of the Earth - the Coriolis force. In the Northern Hemisphere, it deflects currents to the right, and in the Southern Hemisphere, to the left. The speed of currents on average does not exceed 10 m/s, and their depth extends to no more than 300 m.
In the World Ocean there are constantly thousands of large and small currents that circle the continents and merge into five giant rings. The system of currents in the World Ocean is called circulation and is associated primarily with the general circulation of the atmosphere.
Ocean currents redistribute solar heat absorbed by masses of water. They transport warm water heated by the sun's rays at the equator to high latitudes, and cold water
Currents of the World Ocean
Upwelling - the rise of cold waters from the depths of the ocean
UPWELLING | |
In many areas of the World Ocean there are | |
the deep waters “float” to the surface | |
ness of the sea. This phenomenon is called upwelling | |
gom (from the English up - upward and well - to pour out), | |
occurs, for example, if the wind drives away | |
warm surface waters, and in their place | |
colder ones rise. Temperature | |
water in upwelling areas is lower than average | |
low at this latitude, which creates favorable | |
pleasant conditions for plankton development, | |
and, consequently, other marine organizations | |
mov - fish and sea animals that they | |
eat. Upwelling areas are the most important | |
fishing areas of the World Ocean. They | |
are at western shores continents: | |
Peruvian-Chilean - near South America, | |
Californian - near North America, Ben- | |
Gaelic - in South-West Africa, Canary Islands | |
Chinese - in West Africa. |
from the polar regions, thanks to currents, it flows to the south. Warm currents contribute to an increase in air temperature, and cold currents, on the contrary, reduce it. Territories washed by warm currents have a warm and humid climate, while those near which cold currents pass have a cold and dry climate.
The most powerful current in the World Ocean is the cold current of the Western Winds, also called the Antarctic Circumpolar Current (from the Latin cirkum - around). The reason for its formation is strong and stable westerly winds blowing from west to east over vast areas.
areas of the Southern Hemisphere from temperate latitudes to the coast of Antarctica. This current covers an area 2500 km wide, extends to a depth of more than 1 km and transports up to 200 million tons of water every second. There are no large land masses in the path of the Western Winds, and it connects in its circular flow three waters oceans - Pacific, Atlantic and Indian.
The Gulf Stream is one of the largest warm currents in the Northern Hemisphere. It passes through the Gulf of Mexico (English Gulf Stream - Gulf Current) and carries warm tropical waters Atlantic Ocean to high latitudes. This gigantic flow of warm water largely determines the climate of Europe, making it soft and warm. Every second, the Gulf Stream carries 75 million tons of water (for comparison: the Amazon, the deepest river in the world, carries 220 thousand tons of water). At a depth of about 1 km, a countercurrent is observed under the Gulf Stream.
SEA ICE
When approaching high latitudes, ships encounter floating ice. Sea ice frames Antarctica with a wide border and covers the waters of the Arctic Ocean. Unlike continental ice, formed from atmospheric precipitation and covering Antarctica, Greenland, and the islands of the polar archipelagos, this ice is frozen sea water. In the polar regions sea ice perennial, while in temperate latitudes water freezes only in cold seasons.
How does sea water freeze? When the water temperature drops below zero, a thin layer of ice forms on its surface, which breaks under wind waves. It repeatedly freezes into small tiles, then splits again until it forms the so-called ice lard - spongy ice floes, which then grow together. This type of ice is called pancake ice for its resemblance to rounded pancakes on the surface of the water. Areas of such ice, when frozen, form young ice - nilas. Every year this ice gets stronger and thickens. He might become multi-year ice more than 3 m thick, and may melt if currents carry the ice floes to warmer waters.
The movement of ice is called drift. Covered with drifting (or pack) ice
Ice mountains are melting, taking on bizarre shapes
the space around the Canadian Arctic Archipelago, off the coast of Severnaya and Novaya Zemlya. Arctic ice drifting at speeds of several kilometers per day.
ICEBERGS
Colossal pieces of ice often break off from huge ice sheets and set off on their own voyage. They are called “ice mountains” - icebergs. Without them, the ice sheet in Antarctica would constantly grow. In fact, icebergs compensate for melting and provide a balance to the Antarctic state.
Iceberg off the coast of Norway
tic cover. Some icebergs reach gigantic sizes.
When we want to say that some event or phenomenon in our life can have much more serious consequences than it seems, we say “this is just the tip of the iceberg.” Why? It turns out that approximately 1/7 of the entire iceberg is above water. It can be table-shaped, dome-shaped or cone-shaped. The base of such a huge piece of glacier, located under water, can be much larger in area.
Sea currents carry icebergs far from their birthplaces. A collision with such an iceberg in the Atlantic Ocean caused a
construction of the famous ship Titanic in April 1912.
How long does an iceberg live? Ice mountains that break away from the icy Antarctica can float in the waters of the Southern Ocean for more than 10 years. Gradually they are destroyed, split into smaller parts or, by the will of currents, move to warmer waters and melt.
"FRAM" IN ICE
To find out the path of the drifting ice, the great Norwegian traveler Fridtjof Nansen decided to drift on his ship Fram with them. This bold expedition lasted three whole years (1893-1896). Having allowed the Fram to freeze into the drifting pack ice, Nansen planned to move with it to the North Pole area, and then leave the ship and continue the journey by dog sled and skis. However, the drift went further south than expected, and Nansen's attempt to reach the Pole on skis was unsuccessful. Having traveled more than 3,000 miles from the New Siberian Islands to the western coast of Spitsbergen, the Fram collected unique information about drifting ice and the influence of the Earth's daily rotation on its movement.
The border between land and sea is a line that constantly changes its shape. The oncoming waves carry the smallest particles of suspended sand, roll over pebbles, and grind down rocks. Destroying the coast, especially during strong waves or storms, in one place, they engage in “construction” in another.
The area where coastal waves act is the narrow edge of the shore and its underwater slope. Where the destruction of the coast is mainly taking place, above the water, like
As a rule, there are overhanging rocks - cliffs, the waves “gnaw out” niches in them, creating under them
wonderful grottoes and even underwater caves. This type of shore is called abrasive (from the Latin abrasio - scraping). When sea levels change - and this has happened many times in the recent geological history of our planet - abrasion structures could end up under water or, conversely, on land, far from the modern shore. By
For such forms of coastal relief located on land, scientists reconstruct the history of the formation of ancient coasts.
In areas of a leveled coast with shallow depths and a gentle underwater slope, waves deposit (accumulate) material that was transported from the destroyed areas. Beaches are formed here. At high tide, rolling waves move sand and pebbles deep into the shore, creating a long
ny alongshore levees. During low tide, you can see accumulations of shells and seaweed on such ridges.
Ebbs and flows are associated with attraction | ||||
The Moon, the satellite of the Earth, and the Sun - our near- | ||||
the greatest star. If the influences of the Moon and the Sun | ||||
add up (i.e. the Sun and Moon turn out to be | ||||
on the same straight line relative to the Earth, which is | ||||
comes on the days of the new moon and full moon), then the | ||||
The tide reaches its maximum. | ||||
This tide is called spring tide. When | ||||
The Sun and Moon weaken each other's influence, | ||||
minimal tides occur (they are called | ||||
quadrature, they happen between the new moon | ||||
and full moon). | ||||
How do deposits form when | ||||
rough sea? As the waves move toward the shore, | ||||
sorts by size and transfers sandy | To combat coastal erosion as a result of disturbances |
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particles, moving them along the shore. | Barrages made of boulders are often built on beaches |
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TYPES OF SHORE |
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The fjord coast is found in places of flooding | the name of this type of coast). They are educated |
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the sea of deep glacial trenches | occurred when folded structures were flooded by the sea |
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valleys In place of valleys, winding | rock formations parallel to the coastline. |
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bays with steep walls, which are called | A rias bank is formed by flooding |
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are surrounded by fjords. Majestic and beautiful | sea of river valley mouths. |
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fjords dissect the shores of Norway (the most pro- | Skerries are small rocky islands off |
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Sognefjord is long here, its length is 137 km), | coasts subjected to glacial treatment: |
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coast of Canada, Chile. | sometimes these are flooded "ram's foreheads", hills and |
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Dalmatian | shore. | ridges of terminal moraine. |
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small strips of islands frame the coast | Lagoons are shallow parts of the sea, separated |
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Adriatic Sea in the Dalmatia region (from here | away from the water area by a coastal rampart. |
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Benthos (from the Greek benthos - depth) - living organisms and plants living at depth, at the bottom of oceans and seas.
Nekton (from the Greek nektos - floating) are living organisms capable of independently moving through the water column.
Plankton (from the Greek planktos - wandering) are organisms living in water, transported by waves and currents and unable to move independently in water.
ON THE DEEP FLOORS
The ocean floor descends in giant steps from the coast to the underwater abyssal plains. Each such “underwater floor” has its own life, because the conditions of existence of living organisms: illumination, water temperature, its saturation with oxygen and other substances, the pressure of the water column - change significantly with depth. Organisms react differently to the amount of sunlight and water transparency. For example, plants can live only where illumination allows photosynthesis processes to take place (this is an average depth of no more than 100 m).
The littoral zone is a coastal strip periodically drained at low tide. This includes marine animals carried out of the water by waves, which have adapted to live in two environments at once - aquatic
And air. These are crabs
And crustaceans, sea urchins, mollusks, including mussels. In tropical latitudes in the littoral zone there is a border of mangrove forests, and in temperate zones there are “forests” of kelp algae.
Below the littoral zone is the sublittoral zone (down to depths of 200-250 m), the coastal strip of life on the continental shelf. Towards the poles, sunlight penetrates the water very shallowly (no more than 20 m). In the tropics and at the equator, the rays fall almost vertically, which allows them to reach depths of up to 250 m. It is to such depths that algae, sponges, mollusks and light-loving animals, as well as coral structures - reefs, are found in warm seas and oceans. Animals not only attach to the bottom surface, but also move freely in the water column.
The largest mollusk that lives in shallow water is the tridacna (its shell valves reach 1 meter). As soon as the prey swims into the open doors, they slam shut and the mollusk begins to digest the food. Some mollusks live in colonies. Mussels are bivalves that attach their shells to rocks and other objects. Mollusks breathe oxygen
dissolved in water, so they are not found in the deeper levels of the ocean.
Cephalopods - octopuses, octopuses, squids, cuttlefish - have several tentacles and move through the water column due to compression
muscles that allow them to push water through a special tube. Among them there are also giants with tentacles up to 10-14 meters! Starfish, sea lilies, urchins
They are attached to the bottom and corals with special suction cups. Sea anemones, similar to strange flowers, pass their prey between their tentacles-“petals” and swallow it with a mouth opening located in the middle of the “flower”.
Millions of fish of all sizes inhabit these waters. Among them are various sharks - some of the largest fish. Moray eels hide in rocks and caves, and stingrays hide at the bottom, the color of which allows them to blend into the surface.
Below the shelf, an underwater slope begins - the bathyal (200 - 3000 m). Living conditions here change with every meter (temperature drops and pressure rises).
Abyssal - ocean bed. This is the most extensive space, occupying more than 70% of the underwater bottom. Its most numerous inhabitants are foraminifera and protozoan worms. Deep-sea sea urchins, fish, sponges, starfish - all have adapted to the monstrous pressure and are not like their relatives in shallow water. At depths where no one can go Sun rays, marine inhabitants developed adaptations for lighting - small luminous organs.
Land waters make up less than 4% of all water found on our planet. About half of their quantity is contained in glaciers and permanent snow, the rest is in rivers, lakes, swamps, artificial reservoirs, groundwater and underground ice permafrost. All natural waters The lands are called water resources.
The most valuable reserves for humanity are fresh water reserves. There is a total of 36.7 million km3 of fresh water on the planet. They are concentrated primarily in large lakes and glaciers and are unevenly distributed between continents. Antarctica, North America and Asia have the largest reserves of fresh water, South America and Africa have somewhat smaller reserves, and Europe and Australia are the least rich in fresh water.
Groundwater is the water contained in the earth's crust. They are associated with the atmosphere and surface waters and participate in the water cycle on the globe. Underground
Glaciers
- constant snow
Rivers
Lakes
Swamps
The groundwater
- underground permafrost ice
waters are found not only under continents, but also under oceans and seas.
Groundwater forms because some rocks allow water to pass through while others retain it. Atmospheric precipitation falling on the Earth's surface seeps through cracks, voids and pores of permeable rocks (peat, sand, gravel, etc.), and waterproof rocks (clay, marl, granite, etc.) retain water.
There are several classifications of groundwater based on origin, condition, chemical composition and the nature of the occurrence. Water that, after rain or melting snow, penetrates the soil, wets it and accumulates in the soil layer is called soil water. Groundwater lies on the first waterproof layer from the surface of the earth. They are replenished due to the atmosphere
spheral precipitation, filtration of water streams and reservoirs and condensation of water vapor. The distance from the earth's surface to the groundwater level is called depth of groundwater. She
increases in the wet season, when there is a lot of rainfall or snow melts, and decreases in the dry season.
Below the groundwater there may be several layers of deep groundwater, which are held by impermeable layers. Often interstratal waters become pressure. This occurs when layers of rock form a bowl and the water contained within is under pressure. Such groundwater, called artesian, rises up the drilled well and gushes out. Often artesian aquifers occupy a significant area, and then artesian sources have a high and fairly constant flow water. Some famous oases in North Africa arose from artesian springs. Along faults in the earth's crust, artesian waters sometimes rise from aquifers, and between rainy seasons they often dry up.
Groundwater reaches the surface of the Earth in ravines and river valleys in the form sources - springs or springs. They form where a rock aquifer reaches the earth's surface. Because the depth of groundwater varies depending on the season and rainfall, the springs sometimes suddenly disappear, and sometimes they bubble up. The water temperature in the springs may vary. Springs with a water temperature of up to 20 °C are considered cold, warm - with a temperature from 20 to 37 °C, and hot -
Permeable rocks
Waterproof rocks
Types of groundwater
mi, or thermal, - with a temperature above 37 ° C. Most hot springs occur in volcanic areas, where groundwater aquifers are heated by hot rocks and molten magma that comes close to the earth's surface.
Mineral groundwater contains many salts and gases and, as a rule, has healing properties.
The importance of groundwater is very great; it can be classified as a mineral along with coal, oil or iron ore. Groundwater feeds rivers and lakes, thanks to which the rivers do not become shallow in the summer, when little rain falls, and do not dry up under the ice. Humans widely use groundwater: they are pumped out of the ground to supply water to residents of cities and villages, for industrial needs and to irrigate agricultural land. Despite the huge reserves, groundwater is renewed slowly, and there is a danger of its depletion and contamination by domestic and industrial wastewater. Excessive water intake from deep horizons reduces the flow of rivers during low-water periods - the period when the water level is lowest.
A swamp is an area of the earth's surface with excessive moisture and stagnant water regime, in which organic matter accumulates in the form of undecomposed plant remains. Swamps exist in all climate zones and on almost all continents of the Earth. They contain about 11.5 thousand km3 (or 0.03%) of the fresh waters of the hydrosphere. The most swampy continents are South America and Eurasia.
Swamps can be divided into two large groups - wetlands, where there is no well-defined peat layer, and peat bogs where peat accumulates. Wetlands include tropical wetlands, salt mangrove swamps, salt marshes of deserts and semi-deserts, grass swamps of the Arctic tundra, etc. Peat swamps occupy about 2.7 million km, which is 2% of the land area. They are most common in the tundra, forest zone and forest-steppe and, in turn, are divided into lowland, transitional and upland.
Lowland swamps usually have a concave or flat surface, where conditions for moisture stagnation are created. They often form along the banks of rivers and lakes, sometimes in flood zones of reservoirs. In such swamps, groundwater comes close to the surface, supplying the plants growing here with minerals. On
Alder, birch, spruce, sedge, reed, and cattails often grow in lowland swamps. In these bogs, the peat layer accumulates slowly (on average 1 mm per year).
Raised bogs with a convex surface and a thick layer of peat are formed mainly on watersheds. They feed mainly on atmospheric precipitation, which is poor in minerals, so less demanding plants - pine, heather, cotton grass, sphagnum moss - settle in these swamps.
An intermediate position between lowland and upland ones is occupied by transitional swamps with a flat or slightly convex surface.
Swamps evaporate moisture intensively: the most active ones are swamps of the subtropical climate zone, swampy tropical forests, and in temperate climates - sphagnum-sedge and forest swamps. Thus, swamps increase air humidity, change its temperature, softening the climate of the surrounding areas.
Swamps, like a kind of biological filter, purify water from dissolved substances. chemical compounds and solid particles. Rivers flowing through swampy areas are no different from catastrophes.
trophic spring floods and floods, since their flow is regulated by swamps, which gradually release moisture.
Bogs regulate the flow of not only surface water, but also groundwater (especially raised bogs). Therefore, their excessive drainage can harm small rivers, many of which originate in swamps. Swamps are rich hunting grounds: many birds nest here and many game animals live. The swamps are rich in peat, medicinal herbs, mosses and berries. The widespread belief that by growing crops in drained swamps one can get a rich harvest is wrong. Only the first few years are drained peat deposits fertile. Plans for draining swamps require comprehensive studies and economic calculations.
The development of a peat bog is the process of accumulation of peat as a result of the growth, death and partial decomposition of vegetation under conditions of excess moisture and lack of oxygen. The entire thickness of peat in a bog is called a peat deposit. It has a multilayer structure and contains from 91 to 97% water. Peat contains valuable organic and inorganic substances, which is why it has long been used in agriculture, energy, chemistry, medicine and other fields. For the first time, Pliny the Elder wrote about peat as “combustible earth” suitable for heating food in the 1st century. AD In Holland and Scotland, peat was used as fuel in the 12th-13th centuries. An industrial accumulation of peat is called a peat deposit. The largest industrial reserves of peat are in Russia, Canada, Finland and the USA.
Fertile river valleys have long been developed by humans. Rivers were the most important transport routes; their waters irrigated fields and gardens. Populous cities arose and developed on the river banks, and borders were established along the rivers. Flowing water turned the wheels of the mills and later provided electrical energy.
Each river is individual. One is always wide and full of water, while the other has a channel that remains dry for most of the year and only fills with water during rare rains.
A river is a watercourse of significant size, flowing along a depression formed by itself in the bottom of a river valley - a channel. The river with its tributaries forms a river system. If you look down the river, then all the rivers flowing into it from the right are called right tributaries, and those flowing from the left are called left tributaries. The part of the earth's surface and thickness of soils and soils from which the river and its tributaries collect water is called a catchment area.
A river basin is the portion of land that includes a given river system. Between two basins of neighboring rivers there are watersheds,
River basin
The Pakhra River flows through the East European Plain
usually these are hills or mountain systems. Basins of rivers flowing into the same body of water are combined, respectively, into basins of lakes, seas and oceans. The main watershed of the globe is identified. It separates the basins of rivers flowing into the Pacific and Indian oceans on the one hand, and the basins of rivers flowing into the Atlantic and Arctic oceans, on the other. In addition, there are drainage areas on the globe: the rivers flowing there do not carry water to the World Ocean. Such drainless areas include, for example, the basins of the Caspian and Aral seas.
Every river begins at its source. This could be a swamp, a lake, a melting mountain glacier, or groundwater coming to the surface. The place where a river flows into an ocean, sea, lake or other river is called an estuary. The length of a river is the distance along the channel between the source and the mouth.
Depending on their size, rivers are divided into large, medium and small. Swimming pools big rivers usually located in several geographic areas. The basins of medium and small rivers are located within the same zone. According to the flow conditions, rivers are divided into flat, semi-mountain and mountain. Plain rivers flow smoothly and calmly in wide valleys, and mountain rivers rush violently and rapidly through gorges.
The replenishment of water in rivers is called river recharge. It can be snow, rain, glacial and underground. Some rivers, for example those that flow in equatorial regions (Congo, Amazon and others), are fed by rain, since in these areas of the planet it rains all year round. Most rivers are temperate
climatic zone have a mixed diet: in the summer they are replenished by rain, in the spring by melting snow, and in winter they are not allowed to run out of groundwater.
The nature of the behavior of the river according to the seasons of the year - fluctuations in water level, formation and disappearance of ice cover, etc. - is called the river regime. Annually recurring significant increase in water
in the river - flood - on the lowland rivers of the European territory of Russia is caused by intense snow melting in the spring. The rivers of Siberia flowing from the mountains are full of water in the summer when the snow melts
V mountains A short-term rise in water level in a river is called flood It occurs, for example, when heavy rainfall occurs or when snow melts intensively during a thaw in winter. The lowest water level in the river is low water. It is installed in the summer; at this time there is little rain and the river is fed mainly by groundwater. Low water also occurs in winter, during severe frosts.
Floods and floods can cause severe floods: melt or rainwater overwhelms the riverbeds, and rivers overflow their banks, flooding not only their valleys, but also the surrounding area. Water flowing at high speed has enormous destructive power, it demolishes houses, uproots trees, and washes away fertile soil from fields.
Sandy beach on the banks of the Volga
TO DOES IT LIVE IN RIVERS?
IN Not only fish live in rivers. The waters, bottom and banks of rivers are the habitat of many living organisms; they are divided into plankton, nekton and benthos. Plankton includes, for example, green and blue-green algae, rotifers and lower crustaceans. The river benthos is very diverse - insect larvae, worms, mollusks, crayfish. Plants settle on the bottom and banks of rivers - pondweed, reeds, reeds, etc., and algae grow on the bottom. River nekton is represented by fish and some large invertebrates. Among the fish that live in the seas and enter rivers only to spawn are sturgeon (sturgeon, beluga, stellate sturgeon), salmon (salmon, pink salmon, sockeye salmon, chum salmon, etc.). Carp, bream, sterlet, pike, burbot, perch, crucian carp, etc. constantly live in rivers, and grayling and trout live in mountain and semi-mountain rivers. Mammals and large reptiles also live in rivers.
Rivers usually flow at the bottom of extensive relief depressions called river valleys. At the bottom of the valley, the water flow runs along a depression it has created itself - a channel. Water hits one section of the shore, erodes it and carries rock fragments, sand, clay, and silt downstream; in those places where the flow speed decreases, the river deposits (accumulates) the material it carries. But the river carries not only sediments eroded by the river flow; during stormy rains and snow melting, water flowing over the earth's surface destroys the soil, loose soil and carries small particles to streams, which then deliver them to rivers. By destroying and dissolving rocks in one place and depositing them in another, the river gradually creates its own valley. The process of erosion of the earth's surface by water is called erosion. It is stronger where the speed of water flow is higher and where the soils are looser. The sediment that forms the bottom of rivers is called bottom sediments or alluvium.
Wandering channels
In China and Central Asia There are rivers in which the bed can shift by more than 10 m in a day. They, as a rule, flow in easily eroded rocks - loess or sand. In a few hours, a water flow can significantly erode one bank of the river, and deposit washed-away particles on the other bank, where the flow slows down. Thus, the channel shifts - “wanders” along the bottom of the valley, for example, on the Amu Darya River in Central Asia up to 10-15 m per day.
The origin of river valleys can be tectonic, glacial and erosional. Tectonic valleys follow the direction of deep faults in the earth's crust. Powerful glaciers that covered during the global glaciation northern regions Eurasia and North America, moving, plowed deep hollows, in which river valleys later formed. During the melting of glaciers, water flows spread to the south, forming extensive depressions in the relief. Later, streams rushed into these depressions from the surrounding hills, forming a large water flow that built its own valley.
Structure of a lowland river valley
Rapids on a mountain river
DRY RIVERS
There are rivers on our planet that fill with water only during rare rains. They are called "wadis" and are found in deserts. Some wadis reach a length of hundreds of kilometers and flow into dry depressions similar to themselves. Gravel and pebbles at the bottom of dry riverbeds suggest that in wetter periods, wadis could have been full-flowing rivers capable of carrying large sediments. In Australia, dry river beds are called creeks, in Central Asia - uzboi.
The valley of lowland rivers consists of a floodplain (part of the valley that is flooded during high water or during significant floods), a channel located on it, as well as valley slopes with several above the floodplain terraces, descending steps to the floodplain. River channels can be straight, meandering, divided into branches or wandering. Winding channels have bends, or meanders. By eroding the bend near the concave bank, the river usually forms a stretch - a deep section of the channel, its shallow sections are called riffles. The strip in the riverbed with depths most favorable for navigation is called fairway. The water flow sometimes deposits significant amounts of sediment, forming islands. On large rivers, the height of the islands can reach 10 m and the length can be several kilometers.
Sometimes along the river's path there is a ledge of hard rock. The water cannot wash it away and falls down, forming a waterfall. In those places where the river crosses hard rocks that erode slowly, rapids are formed that block the path of the water flow.
IN estuary the water speed slows down significantly,
And the river deposits most of its sediment. Formed delta is a low-lying plain in the shape of a triangle, here the channel is divided into many branches and channels. River mouths flooded by the sea are called estuaries.
There are a great many rivers on Earth. Some of them flow like small silvery snakes within one forest area and then flow into a larger river. And some are truly huge: descending from the mountains, they cross vast plains and carry their waters to the ocean. Such rivers can flow through the territory of several states and serve as convenient transport routes.
When characterizing a river, take into account its length, average annual water flow and basin area. But not all large rivers have all these outstanding parameters. For example, the longest river in the world, the Nile, is far from the deepest, and its basin area is small. The Amazon ranks first in the world in terms of water content (its water flow is 220 thousand m3 / s - this is 16.6% of the flow of all rivers) and in terms of basin area, but is inferior in length to the Nile. The largest rivers are in South America, Africa and Asia.
The longest rivers in the world: Amazon (over 7 thousand km from the source of the Ucayali River), Nile (6671 km), Mississippi with the Missouri tributary (6420 km), Yangtze (5800 km), La Plata with the Parana and Uruguay tributaries (3700 km).
The deepest rivers (having maximum values of average annual water flow): Amazon (6930 km3), Congo (Zaire) (1414 km3), Ganges (1230 km3), Yangtze (995 km3), Orinoco (914 km3).
The largest rivers on the globe (by basin area): Amazon (7,180 thousand km2), Congo (Zaire) (3,691 thousand km2), Mississippi with its tributary of the Missouri (3,268 thousand km2), La Plata with tributaries of the Parana and Uruguay (3,100 thousand km2), Ob (2990 thousand km2).
Volga is the largest river of the East European Plain
MYSTERIOUS NILE
The Nile is a great African river, its valley is the cradle of a vibrant, original culture that influenced the development of human civilization. The powerful Arab conqueror Amir ibn al-Asi said: “There lies a desert, on both sides it rises, and between the heights is the wonderland of Egypt. And all his wealth comes from the blessed river, flowing slowly through the country with the dignity of a caliph.” In its middle course, the Nile flows through the harshest deserts in Africa - the Arabian and Libyan. It would seem that it should become shallow or dry out during the hot summer. But at the height of summer, the water level in the Nile rises, it overflows its banks, flooding the valley, and as it recedes, it leaves a layer of fertile silt on the soil. This is because the Nile is formed from the confluence of two rivers - the White and Blue Nile, the sources of which lie in the subequatorial climatic zone, where in the summer a low pressure area sets in and heavy rainfall occurs. The Blue Nile is shorter than the White Nile, so the one that filled it rainwater reaches Egypt first, followed by the White Nile flood.
Yenisei - great river Siberia
AMAZON - QUEEN OF RIVERS
The Amazon is the largest river on Earth. It is fed by many tributaries, including 17 large rivers up to 3500 km long, which by their size can themselves be considered
to the great rivers of the world. The source of the Amazon lies in the rocky Andes, where its main tributary, the Marañon, flows from the mountain lake Patarcocha. When the Marañon merges with the Ucayali, the river takes on the name Amazon. The lowland through which this majestic river flows is a country of jungle and swamps. On their way to the east, tributaries continually replenish the Amazon. It is full of water throughout the year, because its left tributaries, located in the northern hemisphere, are full of water from March to September,
A the right tributaries, located in the southern hemisphere, are full the other part of the year. During sea tides, a water shaft up to 3.54 meters high enters the mouth of the river from the Atlantic and rushes upstream. Locals They call this wave “vice” - “destroyer”.
MISSISSIPPI - THE GREAT RIVER OF AMERICA
The Indians called the mighty river in the southern part of the North American continent Messi Sipi - “Father of Waters”. Its complex river system with many tributaries looks like a giant tree with a densely branched crown. The Mississippi Basin occupies almost half the territory of the United States of America. Beginning in the Great Lakes region in the north, the high-water river carries its waters south - to the Gulf of Mexico, and its flow is two and a half times more than the Russian Volga River brings to the Caspian Sea. The Spanish conquistador de Soto is considered the discoverer of the Mississippi. In search of gold and jewelry, he went deep into the mainland and in the spring of 1541 he discovered the banks of a huge deep river. One of the first colonists, the Jesuit fathers, who spread the influence of their order in the New World, wrote about the Mississippi: “This river is very beautiful, its width is more than one league; everywhere adjoining it are forests full of game, and prairies where there are many bison.” Before the arrival of European colonialists, vast areas in the river basin were occupied by virgin forests and prairies, but now they can only be seen in national parks, most of the land is plowed.
The waters of rivers and streams, choosing their path, often fall off cliffs and ledges. This is how waterfalls are formed. Sometimes these are very small steps in the riverbed with minor differences in height between the upper section, from where the water falls, and the lower one. However, in nature there are also absolutely gigantic “steps” and ledges, the height of which reaches many hundreds of meters. Both waterfalls are formed when the water “opens up”, i.e. destroys, exposes areas with harder rocks, carrying away material from more pliable areas. The upper ledge (edge), from which the water falls, is a more durable layer, and downstream, tireless waters destroy less durable rock layers. Such a structure, for example, has the world-famous waterfall on the Niagara River (its name in the Iroquois language means “thundering water”), which connects two of the Great Lakes of North America - Erie and Ontario. Niagara Falls is relatively low - only 51 m (for comparison -
Diagram of water movement in Niagara Falls
Cascade of several waterfalls in Norway. 19th century engraving
The Ivan the Great bell tower in the Moscow Kremlin has a height of 81 m), but is more famous than its tall and full-flowing “brothers”. The waterfall became famous not only because of its location in close proximity to large American and Canadian cities, but also because it was well studied.
A water stream, falling from any height to the foot of the slope, forms a depression, a niche, even in fairly strong rocks. But the upper edge is gradually eroded and destroyed by the action of flowing water. The peaks of the ledge collapse, and... The waterfall seems to retreat back, “backing away” up the valley. Long-term observations of Niagara Falls have shown that such “backward” erosion “eats” the upper ledge of the waterfall by about 1 m over 60 years.
In Scandinavia, glacial landforms are to blame for the formation of waterfalls. There, streams from glacier-lined mountain peaks flow from great heights into the fjords.
The huge waterfalls that arose under the influence of tectonics - the internal forces of the Earth - are very impressive. Colossal steps of waterfalls are formed when the river bed is disrupted by tectonic faults. It happens that not one ledge is formed, but several at once. These cascades of waterfalls are incredibly beautiful.
The view of any waterfall is mesmerizing. It's no coincidence that these natural phenomena invariably attract the attention of numerous tourists, often becoming “ business cards» localities and even countries.
VICTORIA FALLS | Churun-meru waterfall - |
"ANGELA'S SALTO" |
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“The smoke that thunders” - so from the language of the locals | |
inhabitants the name “Mosi-oa Tupia” is translated, which | The world's highest waterfall is located in South |
which has long been used to designate this African water | noah America, in Venezuela. Durable quartzite |
pad. The first Europeans to see in 1855 | rocks of the Guiana Highlands, crushed by faults |
this is an amazing creation of nature on the Zambezi River, | mami, form chasms several kilometers long. |
were members of David Livingston's expedition, | Falls into one of these abysses from a height of 1054 m. |
who gave the waterfall its name in honor of the then ruling | water flow of the famous Churun Meru waterfall on |
Queen Victoria. “The water seemed to go deeper | tributary of the Orinoco River. This is its Indian name |
land, since the other slope of the gorge into which it descends | not as well known as the European Angel |
turned around, was only 80 feet away from me" - so | or Salto Angel. I saw it first and flew by |
Livingston described his impressions. Narrow (from 40 | near the waterfall, Venezuelan pilot Angel (in |
up to 100 m) the channel into which the waters of the Zambe flow | translated from Spanish - “angel”). His last name and |
zi, reaches a depth of 119 meters. When all the water of the river | gave a romantic name to the waterfall. Opening |
rushes into the gorge, clouds of water dust, tearing out | of this waterfall in 1935, the “palm tree” was selected |
rising upward, visible from a distance of 35 km! In the splashes | power" at the African Victoria Falls, counting |
There is always a rainbow hanging over the waterfall. | previously the tallest in the world. |
IGUAZU FALLS
One of the most famous and beautiful waterfalls | |
The dominant species in the world is the South American Iguazu, | |
located on the river of the same name, a tributary | |
Paranas. Actually, it’s not even one, but more | |
250 waterfalls, the streams and jets of which rush - | |
flowing from several sides into a funnel-shaped canyon. | |
The largest of the Iguazu Falls, 72 m high, | |
called the "Devil's Throat"! Origin of the establishment | |
the waterfall is associated with the structure of the lava plateau, | |
along which the Iguazu River flows. "Layer Cake" from | |
basalts are broken by cracks and destroyed by uneven | |
numbered, which led to the formation of a peculiar | |
of the staircase, along the steps of which they rush - | |
flowing down the waters of the river. The waterfall is located on the border | |
Argentina and Brazil, so one side is water- | |
pada - Argentinean, along which waterfalls, replacing | |
each other, stretch for more than a kilometer, and the other | |
Some of the waterfalls are Brazilian. | Waterfall in the Rocky Mountains |
Lakes are hollows filled with water - natural depressions on the surface of the land that have no connection with the sea or ocean. For a lake to form, two conditions are necessary: the presence of a natural depression - a closed depression in the earth's surface - and a certain volume of water.
There are many lakes on our planet. Their total area is about 2.7 million km2, that is, approximately 1.8% of the total land area. The main wealth of the lakes is fresh water, so necessary for a person. The lakes contain about 180 thousand km3 of water, and the 20 largest lakes in the world combined contain the majority of all fresh water available to humans.
The lakes are located in a wide variety of natural areas. Most of them are in the northern parts of Europe and the North American continent. There are a lot of lakes in areas where permafrost is common; there are also lakes in drainless areas, in floodplains and river deltas.
Some lakes are filled only during the wet seasons and remain dry the rest of the year - these are temporary lakes. But most lakes are constantly filled with water.
Depending on their size, lakes are divided into very large, with an area exceeding 1,000 km2, large - with an area from 101 to 1,000 km2, medium - from 10 to 100 km2 and small - with an area of less than 10 km2.
Based on the nature of water exchange, lakes are divided into drainage and drainless. Located in the cat
In the valley, lakes collect water from the surrounding areas, streams and rivers flow into them, while at least one river flows out of drainage lakes, and not a single one flows out of drainage lakes. Drainage lakes include Baikal, Ladoga and Onega lakes, and drainage lakes include Lake Balkhash, Chad, Issyk-Kul, and the Dead Sea. The Aral and Caspian Seas are also closed lakes, but due to their large size and regime similar to the sea, these reservoirs are conventionally considered seas. There are so-called blind lakes, for example, formed in the craters of volcanoes. Rivers do not flow into them or flow out of them.
Lakes can be divided into fresh, brackish and saline, or mineral. The salinity of water in fresh lakes does not exceed 1% - such water, for example, in Lake Baikal, Lake Ladoga and Lake Onega. The water of brackish lakes has a salinity from 1 to 25%. For example, the salinity of water in Issyk-Kul is 5-8%o, and in the Caspian Sea - 10-12%o. Lakes in which the water has a salinity of 25 to 47%o are called salt lakes. Mineral lakes contain more than 47% salts. Thus, the salinity of the Dead Sea, lakes Elton and Baskunchak is 200-300%. Salt lakes tend to form in arid areas. In some salt lakes, the water is a solution of salts close to saturation. If such saturation is achieved, then salts precipitate and the lake turns into a self-sediment lake.
In addition to dissolved salts, lake water contains organic and inorganic substances and dissolved gases (oxygen, nitrogen, etc.). Oxygen not only enters the lakes from the atmosphere, but is also released by plants during the process of photosynthesis. It is necessary for life and development aquatic organisms, as well as for the oxidation of organic
Lake in the Swiss Alps
of the substance found in the reservoir. If excess oxygen forms in the lake, it leaves the water into the atmosphere.
According to the nutritional conditions of aquatic organisms, lakes are divided into:
- lakes poor in nutrients. These are deep lakes with clear water, which include, for example, Baikal, Lake Teletskoye;
- lakes with a large supply of nutrients and rich vegetation. These are, as a rule, shallow and warm lakes;
YOUNG AND OLD LAKES
The life of a lake has a beginning and an end. Once formed, it is gradually filled with river sediments and the remains of dead animals and plants. Every year the amount of precipitation at the bottom increases, the lake becomes shallow, overgrown and turns into a swamp. The greater the initial depth of the lake, the longer its life continues. In small lakes, sediment accumulates over many thousands of years, and in deep lakes, over millions of years.
Lakes with an excess amount of organic substances, the oxidation products of which are harmful to living organisms.
Lakes regulate river flow and have a significant impact on the climate of the surrounding areas.
They contribute to an increase in precipitation, the number of days with fogs and generally soften the climate. Lakes raise groundwater levels and affect soils, vegetation and animal world surrounding areas.
Looking at the geographical map, at everyone | ||
you can see lakes on the continents. Some of them are you- | ||
drawn out, others rounded. Some lakes are located | ||
wives in mountainous regions, others in vast | ||
flat plains, some very deep, and | ||
some are quite small. The shape and depth of the lake | ||
ra depend on the size of the basin, which it | ||
occupies. Lake basins are formed by | ||
Most of the world's largest lakes | ||
has a tectonic origin. They dis- | ||
rely in large depressions of the earth's crust on | ||
plains (for example, Ladoga and Onega | ||
lakes) or fill deep tectonic | ||
cracks - rifts (Lake Baikal, Tanganyika, | ||
Nyasa, etc.). | ||
Craters and | ||
calderas of extinct volcanoes, and sometimes lower- | ||
tions on the surface of lava flows. Such lakes | ||
ra, called volcanic, are found, | ||
for example, on the Kuril and Japanese islands, on | ||
Kamchatka, on the island of Java and in other volcanic | ||
certain regions of the Earth. It happens that lava and debris | ||
igneous rocks are blocked up to | ||
river line, in this case a volcano also appears | Lake Baikal |
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nic lake. |
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TYPES OF LAKE BATTLES |
Lake in a trough of the earth's crust Lake in a crater
The basin of Lake Kaali in Estonia is of meteorite origin. It is located in a crater formed as a result of the fall of a large meteorite.
Glacial lakes fill basins that were formed as a result of glacier activity. As it moved, the glacier plowed up softer soil, creating depressions in the relief: long and narrow in some places, and oval in others. Over time, they filled with water, and glacial lakes appeared. There are a lot of such lakes in the north of the North American continent, in Eurasia on the Scandinavian and Kola Peninsulas, in Finland, Karelia and Taimyr. In mountainous regions, for example in the Alps and the Caucasus, glacial lakes are located in karas - bowl-shaped depressions in the upper parts of mountain slopes, in the creation of which small mountain glaciers and snowfields took part. Melting and retreating, the glacier leaves a moraine - an accumulation of sand, clay with inclusions of pebbles, gravel and boulders. If a moraine dams a river flowing from under a glacier, a glacial lake is formed, often having a round shape.
In areas composed of limestones, dolomites and gypsum, as a result of the chemical dissolution of these rocks by surface and groundwater Karst lake basins appear. Thicknesses of sand and clay lying above karst rocks fall into underground voids, forming depressions on the earth's surface, which over time fill with water and become lakes. Karst lakes are also found in caves
rah, they can be seen in the Crimea, the Caucasus, the Urals and other areas.
IN In the tundra, and sometimes in the taiga, where permafrost is widespread, the soil thaws and subsides during the warm season. Lakes appear in small depressions calledthermokarst.
IN river valleys, when a meandering river straightens its bed, old site the riverbed becomes isolated. This is how they are formed oxbow lakes, often horseshoe-shaped.
Dammed, or dammed, lakes arise in the mountains when, as a result of a collapse, a mass of rocks blocks the river bed. For example,
V In 1911, during an earthquake in the Pamirs, a gigantic mountain collapse occurred, it dammed the Murghab River, and Lake Sarez was formed. Lake Tana in Africa, Sevan in Transcaucasia and many other mountain lakes are dammed.
U on the coast of the seas, sand spits can separate the shallow coastal area from the sea area, resulting in the formation lake-lagoon. If sandy-clay deposits fence off flooded river mouths from the sea, estuaries are formed - shallow bays with very salty water. There are many such lakes on the coast of the Black and Azov Seas.
Formation of a dammed or dammed lake
The largest lakes on Earth: the Caspian Sea- | |
lake (376 thousand km2), Verkhnee (82.4 thousand km2), Vik- | |
thorium (68 thousand km2), Huron (59.6 thousand km2), Michigan | |
(58 thousand km2). The deepest lake on the planet - | |
Baikal (1620 m), followed by Tanganyika | |
(1470 m), Caspian Sea-lake (1025 m), Nyasa | |
(706 m) and Issyk-Kul (668 m). | |
The greatest lake on Earth - the Caspian | |
the sea is located in the interior regions of Euro- | |
Zia, it contains 78 thousand km3 of water - more than 40% | |
of the total volume of lake waters in the world, and in terms of area | |
The Black Sea is rising. By sea Caspian lake | |
called because it has many | |
marine characteristics - huge area - | |
dew, large volumes of water, strong storms | |
and a special hydrochemical regime. | fish that remained from the times when the Caspian |
From north to south the Caspian Sea stretches for almost | was connected to the Black and Mediterranean seas. |
1200 km, and from west to east - 200-450 km. | The water level in the Caspian Sea is below |
By origin it is part of the ancient | the world's oceans and changes periodically; at- |
slightly saline Pontic Lake, which existed | The reasons for these fluctuations are not yet clear enough. Me- |
th 5-7 million years ago. During the Ice Age from | The outlines of the Caspian Sea are also visible. At the beginning of the 20th century. |
Arctic seas, seals entered the Caspian Sea, | the level of the Caspian Sea was approximately -26 m (from |
lorfish, salmon, small crustaceans; is in this | bearing to the level of the World Ocean), in 1972 |
sea-lake and some Mediterranean species | the lowest position was recorded for |
last 300 years - -29 m, then sea-lake level - |
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ra began to rise slowly and is now |
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it is approximately -27.9 m. The Caspian Sea had about |
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70 names: Hyrkan, Khvalyn, Khazar, |
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Saraiskoe, Derbentskoe and others. Its modern |
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The sea received its name in honor of the ancient |
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men of the Caspians (horse breeders) who lived in the 1st century BC. on |
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its northwest coast. |
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The deepest lake on the planet Baikal (1620 m) |
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located in the south of Eastern Siberia. It is located |
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located at an altitude of 456 m above sea level, its length |
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636 km, and the greatest width in the central hour is |
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tee - 81 km. There are several versions of the origin |
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the name of the lake, for example, from the Turkic-language Bai- |
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Kul - “rich lake” or from the Mongolian Bai- |
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gal Dalai - “big lake”. There are 27 islands on Baikal |
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moats, the largest of which is Olkhon. Into the lake |
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About 300 rivers and streams flow in, and only flow out |
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Angara river. Baikal is a very ancient lake, it |
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approximately 20-25 million years. 40% plants and 85% vi- |
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The species of animals living in Lake Baikal are endemic |
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(that is, they are found only in this lake). Volume |
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water in Baikal is about 23 thousand km3, which is |
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20% of the world and 90% of Russian freshwater reserves |
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water. Baikal water is unique - extraordinary - |
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but transparent, clean and oxygenated. |
its history has repeatedly changed shape. Se- |
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the faithful shores of the lakes are rocky, steep and very |
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picturesque, and the southern and southeastern ones are predominantly |
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significantly low, clayey and sandy. Shores |
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The Great Lakes are densely populated and are located here. |
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powerful industrial areas and the largest cities |
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USA: Chicago, Milwaukee, Buffalo, Cleveland, |
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Detroit, also the second largest city of Cana- |
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y - Toronto. Bypassing rapid sections of rivers, |
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connecting the lakes, canals were built and |
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solid waterway sea vessels from the Great |
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lakes into the Atlantic Ocean with an approximate length of |
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lo 3 thousand km and a depth of at least 8 m, accessible |
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for large sea vessels. | ||||||||
African Lake Tanganyika is the most |
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longest on the planet, it was formed in tecto- |
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nic depression in the East African zone |
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faults. | Maximum depth | Tanganyika |
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1470 m, it is the second deepest lake in the world after |
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Baikal. Along the coastline, the length of |
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the second one is 1900 km, passes the border of four African |
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Canadian states - Burundi, Zambia, Tanzania |
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The lake is home to 58 species of fish (omul, whitefish, grayling, | and the Democratic Republic of the Congo. Tanganyika |
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taimen, sturgeon, etc.) and lives a typical sea mammal | a very ancient lake, about 170 en- |
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hoarding - Baikal seal. | endemic fish species. Living organisms inhabit |
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In the eastern part of North America in the basin | lake to a depth of about 200 meters, and below in the water |
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not the St. Lawrence River are the Great | contained | a large number of | hydrogen sulfide. |
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lakes: Superior, Huron, Michigan, Erie and Ontario. | The rocky shores of Tanganyika are indented by numerous |
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They are arranged in steps, the difference in height | lined bays and bays. | |||||||
the first four are not | ||||||||
rises 9 m, and only the lower | ||||||||
here, Ontario, is located | ||||||||
almost 100 m below Erie. | ||||||||
connected | ||||||||
short | ||||||||
high-water | ||||||||
rivers. On the Niaga River | ||||||||
connecting | ||||||||
Niagara formed | ||||||||
50 m). Great Lakes - | ||||||||
greatest | cluster | |||||||
(22.7 thousand km3). They will form | ||||||||
melted during the melting | ||||||||
huge | ||||||||
of the first cover in the northern | ||||||||
North American- | ||||||||
continent | ||||||||
Perennial accumulations of ice in the highlands and cold zones of the Earth are called glaciers. All natural ice unite into the so-called glaciosphere - the part of the hydrosphere that is in a solid state. It includes the ice of cold oceans, the ice caps of mountains, and icebergs that have broken off ice mountains from ice sheets. In the mountains, glaciers are formed from snow. First, when snow recrystallizes as a result of alternating melting and new freezing of water inside the snow column, firn is formed.
Distribution of ice on Earth during the Ice Age
which then turns into ice. Under the influence of gravity, ice moves in the form of ice streams. The main condition for the existence of glaciers - both small and large - is constant low temperatures during most of the year, at which the accumulation of snow prevails over its melting. Such conditions exist in the cold regions of our planet - the Arctic and Antarctic, as well as in the highlands.
ICE AGES
IN THE HISTORY OF THE EARTH
IN Several times in the history of the Earth, severe climate cooling led to the growth of glaciers
And the formation of one or more ice sheets. This time is called glacial or
ice ages.
IN During the Pleistocene (the era of the Quaternary period of the Cenozoic era), the area covered by glaciers was almost three times larger than the modern one. At that time
V Huge ice sheets arose in the mountains and plains of polar and temperate latitudes, which, growing, covered vast territories in temperate latitudes. You can imagine what the Earth looked like at that time by looking at Antarctica or Greenland.
How do they learn about those ancient ice ages? Moving along the surface, the glacier leaves its traces - the material that it took with it as it moved. Such material is called moraine. The stages of their standing glaciers mark their
Movement of the earth's crust under the colossal load of the ice sheet (1) and after its removal (2)
lami of the terminal moraine. Often, by the name of the place that the glacier reached, it is called a glacial area. The furthest glacier on the territory of Eastern Europe reached the Dnieper valley, and this glaciation is called the Dnieper. In North America, traces of maximum southward movement of glaciers belong to two glaciations: in the state of Kansas (Kansas glaciation) and Illinois (Illinois glaciation). The last glaciation reached Wisconsin during the Wisconsin Ice Age.
The Earth's climate changed dramatically during the Quaternary, or Anthropocene, period, which began 1.8 million years ago and continues to this day. What caused this enormous cooling is a question that scientists are trying to solve.
Dozens of hypotheses try to explain the appearance of huge glaciers by a variety of terrestrial and cosmic causes - the fall of giant meteorites, catastrophic volcanic eruptions, changes in the direction of ocean currents. The hypothesis of the Serbian scientist Milankovic, proposed in the last century, was very popular, who explained climate change by periodic fluctuations in the inclination of the planet’s rotation axis and the distance of the Earth from the Sun.
Glaciers of Spitsbergen
Glaciation moraines
The ice sheets that currently exist are the remnants of huge ice sheets that existed in temperate latitudes during the last glacial periods. And although today they are not as large as in the past, their size is still impressive.
One of the most significant is the Antarctic Ice Sheet. The maximum thickness of its ice exceeds 4.5 km, and its distribution area is almost 1.5 times larger than the area of Australia. From several centers of the dome, the ice of many glaciers spreads in different directions. It moves in the form of huge streams at a speed of 300-800 m per year. Occupying the entire Antarctica, the cover in the form of outlet glaciers flows into the sea, giving life to numerous icebergs. Glaciers lying, or rather floating, in the area of the coastline are called shelf glaciers, since they are located in the area of the underwater edge of the continent - the shelf. Such ice shelves exist only in Antarctica. The largest ice shelves are in West Antarctica. Among them is the Ross Ice Shelf, on which the American Antarctic station McMurdo is located.
Another colossal ice sheet is in Greenland, occupying more than 80% of it
Foothill Glacier
himself big island peace. Greenland's ice accounts for about 10% of all ice on Earth. The speed of ice flow here is much less than
V Antarctica. But Greenland also has its own record holder - a glacier that moves at a very high speed - 7 km per year!
Reticulate glaciation characteristic of the polar archipelagos - Franz Josef Land, Spitsbergen, and the Canadian Arctic Archipelago. This type of glaciation is transitional between cover and mountain. In plan, these glaciers resemble a honeycomb grid, hence the name. Peaks, pointed peaks, rocks, and areas of land protrude from under the ice in many places, like islands in the ocean. They are called nunataks. "Nunatak" is an Eskimo word. This word came into scientific literature thanks to the famous Swedish polar explorer Nils Nordenskiöld.
TO The same “half-cover” type of glaciation also includesfoothill glaciers. Often a glacier descending from the mountains along a valley reaches their feet and emerges with wide blades
V melting zone (ablation) to the plain (this type of glaciers is also called Alaskan) or even
on the shelf or in lakes (Patagonian type). Foothill glaciers are among the most spectacular and beautiful. They are found in Alaska, northern North America, Patagonia, the extreme south of South America, and Spitsbergen. The most famous is the Malaspina foothill glacier in Alaska.
Reticulate glaciation of Svalbard
Where latitude and altitude above sea level do not allow snow to melt during the year, glaciers appear - accumulations of ice on mountain slopes and peaks, in saddles, depressions and niches on the slopes. Over time, the snow becomes
spins into firn and then into ice. Ice has the properties of a viscoplastic body and is capable of flow. At the same time he grinds and plows
the surface on which it moves. In the structure of a glacier, a zone of accumulation, or accumulation, of snow and a zone of ablation, or melting, are distinguished. These zones are separated by a food boundary. Sometimes it coincides with the snow line, above which there is snow throughout the year. The properties and behavior of glaciers are studied by glaciologists.
WHAT ARE THERE ARE GLACIERS
Small hanging glaciers lie in depressions on the slopes and often extend beyond the snow line. These are many glaciers of the Alps and Caucasus -
Randklufts - side cracks separating the glacier from the rocks
Bergschrund - crack in the area
glacier supply, separating the stationary and mobile
glacier parts
Median and lateral moraines
Transverse cracks on the glacier tongue
Basic moraine - material beneath a glacier
behind. Tar glaciers fill cup-shaped depressions on the slope - cirques, or cirques. In the lower part, the cirque is limited by a transverse ledge - a crossbar, which is a threshold beyond which the glacier has not crossed for many hundreds of years.
Many mountain-valley glaciers, like rivers, merge from several “tributaries” into one large one that fills the glacial valley. Such glaciers of especially large size (they are also called dendritic or tree-like) are characteristic of the highlands of the Pamirs, Karakoram, Himalayas, and Andes. For each region, there are also more detailed divisions of glaciers.
Summit glaciers occur on rounded or leveled mountain surfaces. The Scandinavian mountains have leveled summit surfaces - plateaus, on which this type of glaciers is common. The plateaus break off with sharp ledges towards the fjords - ancient glacial valleys that have turned into deep and narrow sea bays.
The uniform movement of ice in a glacier can give way to sudden movements. Then the glacier tongue begins to move along the valley at a speed of up to hundreds of meters per day or more. Such glaciers are called pulsating. Their ability to move is due to accumulated tension
V glacial thicker. As a rule, constant observations of a glacier allow one to predict the next pulsation. This helps prevent tragedies like the one that occurred in the Karmadon Gorge in 2003, when the pulsation of the Kolka glacier in the Caucasus caused many settlements flowering valley were buried under chaotic piles of ice blocks. Pulsating glaciers like these are not that uncommon.
V nature. One of them, the Bear Glacier, is located in Tajikistan, in the Pamirs.
Glacial valleys have U shape and resemble a trough. Their name - trog (from German Trog - trough) is connected with this comparison.
When a mountain peak is covered on all sides by glaciers, gradually destroying the slopes, sharp pyramidal peaks are formed - carlings. Over time, neighboring circuses may merge.
Edge of a glacier in the Himalayas
Debris on the surface of a glacier in the Alps
Rivers fed by glaciers, i.e. flowing out from under the glaciers, very muddy and stormy during the melting period in the warm season and, on the contrary, become clean and transparent in winter and autumn. The terminal moraine ridge is sometimes a natural dam for a glacial lake. During rapid melting, the lake can erode the shaft, and then a mudflow is formed - a mud-stone flow.
WARM AND COLD GLACIERS
On the glacier bed, i.e. the part that comes into contact with the surface may have a different temperature. In the highlands of temperate latitudes and in some polar glaciers, this temperature is close to the melting point of ice. It turns out that a layer of melt water forms between the ice itself and the underlying surface. The glacier moves along it, like lubricant. Such glaciers are called warm, in contrast to cold ones, which are frozen to the bed.
Let’s imagine a snowdrift melting in the spring. As it gets warmer, the snow begins to settle, its boundaries become smaller, retreating from the “winter” ones, streams run from under it... And on the surface of the earth, everything that has accumulated on and in the snow over many years remains lying. winter months: all kinds of dirt, fallen branches and leaves, debris. Now let's try to imagine
imagine that this snowdrift is several million times larger, which means that the pile of “garbage” after it melts will be the size of a mountain! When a large glacier melts, which is also called retreat, it leaves behind even more material - because its ice volume contains much more “garbage”. All inclusions left by a glacier after melting on the surface of the earth are called moraine or glacial deposits.
dynamic. After melting, such moraines look like long mounds stretching along the slopes down the valley.
The glacier is in constant motion. As a viscoplastic body, it has the ability to flow. Consequently, the fragment that fell on him from the cliff, after some time, may turn out to be quite far from this place. These fragments are collected (accumulated), as a rule, at the edge of the glacier, where the accumulation of ice gives way to melting. The accumulated material follows the contours of the glacier tongue and has the appearance of a curved embankment, partially blocking the valley. When the glacier retreats, the terminal moraine remains in its original place, gradually being eroded by meltwater. When the glacier retreats, several banks of terminal moraines may accumulate, which will indicate intermediate positions his tongue.
The glacier has retreated. A moraine swell remained in front of its front. But the melting continues. And behind the final moraine melted ice begins to accumulate -
rocky waters. A glacial lake appears, which is held back by a natural dam. When such a lake breaks through, a destructive mud-stone flow - a mudflow - often forms.
As the glacier moves down the valley, it destroys its base. Often this process, which is called "exaration", occurs unevenly. And then steps are formed in the glacier bed - crossbars (from German Riegel - barrier).
The moraines of cover glaciers are much more extensive and diverse, but they are less well preserved in the relief.
Glacier deposits
After all, as a rule, they are more ancient. And tracing their location on the plain is not as easy as in a mountain glacial valley.
In the last ice age, a huge glacier moved from the region of the Baltic crystalline shield, from the Scandinavian and Kola Peninsula. Where the glacier plowed out the crystalline bed, elongated lakes and long ridges - selgi - formed. There are many of them in Karelia and Finland.
It was from there that the glacier brought fragments of crystalline rocks - granites. During the long transportation of rocks, ice abraded the uneven edges of the fragments, turning them into boulders. To this day, such granite boulders are found on the surface of the earth in all areas of the Moscow region. Fragments brought from afar are called erratic. From the maximum stage of the last glaciation - the Dnieper, when the end of the glacier reached the valleys of the modern Dnieper and Don, only moraines and glacial boulders have been preserved.
After melting, the cover glacier left behind a hilly space - a moraine plain. In addition, numerous streams of melted glacial waters burst out from under the edge of the glacier. They eroded the bottom and terminal moraines, carried away thin clay particles and left sandy fields in front of the glacier's edge - outwash (from the Il. sand - sand). Melt water often washed tunnels under melting glaciers that had lost their mobility. In these tunnels, and especially when exiting from under the glacier, washed-up moraine material (sand, pebbles, boulders) accumulated. These accumulations are preserved in the form of long winding shafts - they are called ridges.
IN In cold climates, water in the depths and on the surface freezes to a depth of 500 m or more. Over 25% of the Earth's entire land surface is occupied by permafrost.
IN our country has more than 60% of such territory, because almost all of Siberia lies in its distribution zone.
This phenomenon is called perennial or permafrost. However, the climate can change toward warming over time, so the term "perennial" is more appropriate for this phenomenon.
IN Summer seasons - and they are very short and fleeting here - the top layer of surface soils can thaw. However, below 4 m there is a layer that never thaws. Ground water can be either under this frozen layer, or preserved in a liquid state between permafrost strata (it forms water lenses - taliks) or above the frozen layer. The top layer that is subject to freezing and thawing is calledactive layer.
POLYGONAL SOILS
Ice in the ground can form ice veins. They often appear in frostbite areas (formed by severe frosts) cracks filled with water. When this water freezes, the soil between the cracks begins to compress, because ice occupies a larger area than water. A slightly convex surface is formed, framed by depressions. Such polygonal soils cover a significant part of the tundra surface. When the short summer arrives and the ice veins begin to thaw, entire spaces are formed that look like a lattice of pieces of land surrounded by water “channels.”
Among the polygonal formations, stone polygons and stone rings are widespread. With repeated freezing and thawing of the ground, freezing occurs, pushing larger fragments contained in the soil to the surface by ice. In this way, soil is sorted, since its small particles remain in the center of the rings and polygons, and large fragments are shifted to their edges. As a result, shafts of stones appear, framing smaller material. Mosses sometimes settle on it, and in the fall the stone polygons amaze with their unexpected beauty:
bright mosses, sometimes with cloudberry or lingonberry bushes, surrounded on all sides gray stones, look like specially made garden beds. In diameter, such polygons can reach 1-2 m. If the surface is not flat, but inclined, then the polygons turn into stone strips.
The freezing of debris from the ground leads to the formation of a chaotic accumulation of large stones on the top surfaces and slopes of mountains and hills in the tundra zone, merging into stone “seas” and “rivers.” There is a name for them “kurums”.
BULGUNNYAKHI
This Yakut word denotes amazing
body shape of the relief - a hill or hillock with a forest | ||
ice core inside. It is formed thanks to | ||
an increase in the volume of water when freezing in the over- | ||
permafrost layer. As a result, the ice rises | ||
the surface thickness of the tundra and a mound appears. | ||
Large bulgunnyakhs (in Alaska they are called es- | ||
the Kimos word "pingo") can reach up to | Formation of polygonal soils |
|
30-50 m height. |
||
On the surface of the planet, not only belts of continuous permafrost stand out in cold natural zones. There are areas with so-called island permafrost. It exists, as a rule, in the highlands, in harsh places with low temperatures, for example in Yakutia, and are remnants - “islands” - of the former, more extensive permafrost belt, preserved since the last ice age
The world's oceans are an incredibly complex, multifaceted system that has not been fully studied to date. Water in large water pools should not be stationary, as this would quickly lead to a large-scale environmental disaster. One of the most important factors in maintaining balance on the planet is the currents of the World Ocean.
Reasons for the formation of currents
An ocean current is a periodic or, on the contrary, constant movement of impressive volumes of water. Very often, currents are compared to rivers, which exist according to their own laws. Water circulation, its temperature, power and flow speed - all these factors are determined by external influences.
The main characteristics of ocean currents are direction and speed.
The circulation of water flows in the World Ocean occurs under the influence of physical and chemical factors. These include:
- Wind. Under the influence of strong air flow water moves on the ocean surface and at shallow depths. The wind has no effect on deep-sea currents.
- Space. The influence of cosmic bodies (Sun, Moon), as well as the rotation of the Earth in orbit and around its axis leads to the displacement of layers of water in the World Ocean.
- Different indicators of water density- what determines the appearance of ocean currents.
Rice. 1. The formation of currents largely depends on the influence of space.
Direction of currents
Depending on the direction of water flows, they are divided into 2 types:
- Zonal- moving to the East or West.
- Meridional- directed to the North or South.
There are other types of currents, the appearance of which is caused by ebbs and flows. They are called tidal, and they are most powerful in the coastal zone.
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Sustainable are called currents in which the strength of the flow and its direction remain unchanged. These include the Southern Trade Wind and Northern Trade Wind Currents.
If the flow changes, then it is called unstable. This group includes all surface currents.
Our ancestors have known about the existence of currents since time immemorial. During shipwrecks, sailors threw corked bottles into the water with notes containing the coordinates of the incident, requests for help, or words of farewell. They knew for sure that sooner or later their messages would reach people precisely thanks to currents.
Warm and cold currents of the World Ocean
The formation and maintenance of climate on the globe is greatly influenced by ocean currents, which, depending on the temperature of the water, can be warm or cold.
Water streams whose temperature is above 0 are called warm.
These include the Gulf Stream, Kuroshio, Alaskan and others. They usually move from low to high latitudes.
The warmest current in the world's oceans is El Niño, whose name means Christ Child in Spanish. And this is not without reason, since a strong and full of surprises current appears on the globe on Christmas Eve.
Fig.2. El Niño is the warmest current.
Cold currents have a different direction of movement, the largest of which are the Peruvian and Californian.
The division of ocean currents into cold and warm is very arbitrary, since it shows the ratio of the temperature of the water in the flow to the temperature of the surrounding water. For example, if the water in the flow is warmer than in the surrounding water space, then such a flow is called thermal, and vice versa.
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This I know
2. What are the reasons for the formation of currents?
The main reason for the formation of currents is wind. In addition, the movement of water is affected by the difference in its temperature, density, and salinity.
3. What is the role of ocean currents?
Ocean currents influence climate formation. Currents redistribute heat on Earth. Planktonic organisms move through currents.
4. Name the types of ocean currents and give examples of them?
Currents of origin are wind (Western Wind Current), tidal, or density.
Temperature currents can be warm (Gulf Stream) or cold (Benguela).
Stability currents can be permanent (Peruvian) or seasonal (currents of the northern part of the Indian Ocean, El Nino)
5. Match current – warm (cold):
1) current of the Western winds
2) Gulf Stream
3) Peruvian
4) Californian
5) Kuroshio
6) Benguela
A) warm
B) cold
I can do this
6. Give examples of the interaction between the ocean and the atmosphere.
Currents redistribute heat and influence air temperature and precipitation formation. Sometimes the interaction of currents and the atmosphere leads to the formation of unfavorable and dangerous weather phenomena.
7. Characterize the flow of the Western winds according to plan:
1. Geographical location
The current bends between 400 and 500 S. Earth.
2. Type of flow
A) according to the properties of water (cold, warm)
The current is cold.
B) by origin
The current of the Western Winds is wind-driven in origin. It is caused by the westerly transfer of winds in temperate latitudes.
C) by stability (permanent, seasonal)
The flow is constant.
D) by location in the water column (surface, deep, bottom)
The current is superficial.
8. In ancient times, not knowing the real reasons for the formation of currents in the Ocean, sailors believed that Neptune - the Roman god of the seas - could drag a ship into the ocean depths. Using information from popular science and fiction, Internet, collect materials about ships whose disappearance is associated with currents. Present the materials in the form of drawings, essays, reports.
Secrets Bermuda Triangle
The Bermuda Triangle or Atlantis is a place where people disappear, ships and planes disappear, navigation instruments fail, and almost no one ever finds the crashed. This hostile, mystical, ominous country for humans instills such great horror in the hearts of people that they often simply refuse to talk about it.
Few people knew about the existence of such a mysterious and amazing phenomenon called the Bermuda Triangle a hundred years ago. Actively occupy people's minds and make them come forward various hypotheses and the theory of this mystery of the Bermuda Triangle began in the 70s. last century, when Charles Berlitz published a book in which he extremely interestingly and fascinatingly described the stories of the most mysterious and mystical disappearances in this region. After this, journalists picked up the story, developed the theme, and the history of the Bermuda Triangle began. Everyone began to worry about the secrets of the Bermuda Triangle and the place where the Bermuda Triangle or the missing Atlantis is located.
This wonderful place or the lost Atlantis is located in the Atlantic Ocean off the coast of North America - between Puerto Rico, Miami and Bermuda. Located in two climate zones at once: top part, large - in the subtropics, lower - in the tropics. If these points are connected to each other by three lines, the map will show a large triangular figure, the total area of which is about 4 million square kilometers. This triangle is quite arbitrary, since ships also disappear outside its borders - and if you mark on the map all the coordinates of disappearances, flying and floating Vehicle, then it will most likely turn out to be a rhombus.
For knowledgeable people, the fact that ships often crash here does not cause much surprise: this region is not easy to navigate - there are many shoals, great amount fast water and air currents, cyclones often arise and hurricanes rage.
Water currents. Gulf Stream.
Almost the entire western part of the Bermuda Triangle is crossed by the Gulf Stream, so the air temperature here is usually 10°C higher than in the rest of the territory of this mysterious anomaly. Because of this, in places where atmospheric fronts of different temperatures collide, you can often see fog, which often amazes the minds of overly impressionable travelers. The Gulf Stream itself is very fast current, the speed of which often reaches ten kilometers per hour (it should be noted that many modern transoceanic ships move not much faster - from 13 to 30 km/h). An extremely fast flow of water can easily slow down or increase the movement of a ship (here it all depends on which direction it is sailing). It is not surprising that ships of weaker power in earlier times easily went off course and were carried completely in the wrong direction, as a result of which they crashed and disappeared forever in the oceanic abyss.
In addition to the Gulf Stream, strong but irregular currents constantly appear in the Bermuda Triangle area, the appearance or direction of which is almost never predictable. They are formed mainly under the influence of tidal waves in shallow water and their speed is as high as that of the Gulf Stream - about 10 km/h. As a result of their occurrence, whirlpools often form, causing trouble for small ships with weak engines. It is not surprising that if in former times a sailing ship got here, it would not be easy for it to get out of the whirlwind, and under particularly unfavorable circumstances, one might even say impossible.
In the east of the Bermuda Triangle is the Sargasso Sea - a sea without shores, surrounded on all sides instead of land by strong currents of the Atlantic Ocean - the Gulf Stream, North Atlantic, North Passat and Canary.
Outwardly, it seems that its waters are motionless, the currents are weak and inconspicuous, while the water here is constantly moving, since water flows, pouring into it from all sides, rotate the sea water clockwise. Another remarkable thing about the Sargasso Sea is the huge amount of algae in it (contrary to popular belief, there are also areas with completely clear water here). When in former times ships drifted here for some reason, they became entangled in dense sea plants and, falling into a whirlpool, albeit slowly, they were no longer able to get out.
Geography lesson V 7th grade e
Topic: “Ocean Currents”
Target: reveal the causes of circular motion surface waters, give an idea about general scheme surface currents in the World Ocean.
Tasks:
To form an idea of ocean currents, the reason for their occurrence, types of currents and their use.
identify general patterns of ocean currents
Continue training in working with contour maps, identifying patterns, reading atlas maps.
To cultivate an aesthetic perception of geographical objects
Equipment: textbook, atlas, map of the oceans, physical map of the hemispheres, presentation, geographic simulator, test, portraits of travelers (H. Columbus, T. Heyerdahl).
Main content: ocean currents. Reasons for the formation of ocean currents. Types of ocean currents. The main surface currents of the World Ocean. The importance of ocean currents.
Lesson type:
combined.
DURING THE CLASSES
Organizing time
Good morning, guys! Take a seat and check that you are ready for the lesson and that everything is in place. Today we have not just a lesson - today we have a holiday, because guests came to us - geography teachers from all over our region. We were expecting guests, and today, putting aside all preparatory worries, let's plunge into the world of the wonderful science of geography.
Checking homework.
In the last lesson, we studied the topic...climatic zones and regions of the earth. Let's remember what we talked about in the last and previous lessons.
1. Go to the board to complete an individual task
Draw a diagram of atmospheric circulation using colored crayons (Task card, blue, red and green chalk)
2.An individual test of our geographic simulator on questions will be completed on a laptop
3. Let’s remember what a climate zone is?
Climate zone –
What are the different climate zones? (main and transitional)
What prefix do we use to denote the transitional climate zone (Sub)
How many main belts? (7)
Name the main climatic zones (equatorial, tropical, temperate, Arctic, Antarctic)
Show the main climate zones on the map...
How many transition belts? (6)
Name the transitional climatic zones (2 subequatorial, 2 subtropical, subarctic, subantarctic)
Show the transition zones on the map...
What is the difference between main and transition belts.
Do all zones have climatic regions (no)
In which climate zone there are no climatic regions
Name and show them on the map of the temperate zone of Eurasia (temperate continental, continental, sharply continental, monsoon)
4. Let’s listen to what you wrote in your home mini-essay “I would like to live in the ...... belt, because .....
Let's see how you coped with the task... test completed
Updating knowledge
You and I remembered what we studied and it’s time for us to turn to new material, but it won’t be entirely new for us. In the 6th grade we already became acquainted with the peculiarities of the nature of the Earth.
And today we will move from atmospheric processes to water ones.
What is the name of the water layer of the Earth? (hydrosphere)
And the symbol of our lesson will be this picture . It depicts the famous Norwegian traveler Thor Heyerdahl. (photo)
In 1947, he and 5 like-minded people built a raft of 9 balsa wood logs and named it Kon-Tiki. In 101 days the brave navigator crossed over Pacific Ocean.
And in 1969, he undertook a new dangerous expedition to prove the possibility of African peoples crossing the Atlantic Ocean.
He and six of his followers built a boat from papyrus and named it "Ra". Their first trip was unsuccessful. On next year They again went out to the ocean on a papyrus boat and this time reached their goal in 57 days.
Let's look at the map: Thor Heyerdahl sailed by boat from the port of Safi (32 0 With. w. and 9 0 h. d.) to the island of Barbados (13 0 With. w. and 59 0 h. d.). Follow its route on a map of the oceans. What helped the traveler along the way?
A good way to travel is to travel with the help of ocean currents. And in order to use it, you need to get acquainted with the currents
The topic of our lesson, you guessed it– ocean currents
Let's open our notebooks and write down the date and topic of our lesson.
What do you guys think, what questions do we face in this topic?
What are ocean currents?
What types of currents are there?
How are they formed?
How do people use ocean currents?
To get answers to the questions that interest us, we need to turn to our main source of knowledge. What is this? Textbook. Let's open the textbook page and find and read what an ocean current is.
Ocean current -
People have known about ocean currents for a long time. Historical information prepared for us...
(MESSAGE ABOUT THE HISTORY OF THE DISCOVERY OF OCEAN CURRENTS)
What causes the formation of ocean currents in the World Ocean?
VIDEO
What reason leads to the formation of currents (due to the influence of constant winds). What constant winds do we know? (Task at the board)But there are several other reasons that affect the direction of currents:
1. Constant winds.2. Outlines of continents.
3. Bottom topography
4
. The rotation of the Earth around its axis.
Let's turn to another reliable source of geographic information - a map. How are ocean currents shown on a map? (arrows)
The North Atlantic Current off the coast of Scandinavia has a temperature of +10 0
S. What kind of current is this?(
Warm)
And the Peruvian Current off the coast of South America has a temperature of +19 0 S, what is it? (Cold).
What's the contradiction? (+10 0 C - warm, + 19 0 C – cold)What is the question?
Which currents are called cold and which are called warm?
Let's work and fill out the table you have on your desk
Let's write it down
Current name
Color on the map
Current water temperature
Ocean surface temperature
Temperature comparison
Current type
North Atlantic
red
warm
Peruvian
blue
cold
Conclusion: A current is cold if its temperature is several degrees lower than the temperature of the surrounding ocean water….
Read the page in the textbook and compare whether we made the right conclusion?
- Warm current - This is a current whose water temperature is several degrees higher than the temperature of the surrounding water.
- Cold current - This is a current whose temperature is several degrees lower than the surrounding water.
Find on the map and mark the following currents: Gulf Stream, Canary, Peruvian, Labrador, West Wind Current, Kuroshio.
Which ones are warm? Cold? What pattern did you notice in the arrangement of these currents? ( Warm currents move from the equator, cold currents move from the poles, close, and flow counterclockwise.)
Look carefully at the map. What conclusions can be drawn by analyzing current patterns in the northern and southern hemispheres?
The direction of currents clockwise and counterclockwise is influenced by the rotation of the Earth around its axis. North of the equator, currents bend to the right, south of the equator, to the left. This phenomenon is called the Coriolis effect, named after the French mathematician Gaspard de Coriolis who described it. This is a law of physics and you will study it in high school. In the northern hemisphere, currents travel clockwise, while in the southern hemisphere they travel counterclockwise.
Fizminutka
Let us take a break from our research and warm up. What phenomena can be found in the ocean? Waves, storm, hurricane, tsunami... Let's try to depict these phenomena... wave... higher... the storm begins... A hurricane... during a sea earthquake a tsunami is formed... quieter, quieter.... We moor to the shore... that is, at the desk. Let's warm up... Let's continue.
– Are all currents driven by wind?
If the flow of water encounters an obstacle (land or rising bottom relief), it divides, bending around the obstacle from different sides. The flow also, if it encounters an obstacle, is most often divided into twosewage currents
– When the West Wind Current, which is a wind current, collides, one drain current is formed, and the West Wind Current continues to move on. But there are cases when the wind current ceases to exist as a result of a collision with the mainland, and instead of it two waste currents are formed. Find examples on the map.(California and Alaska, East Australian and Inter-trade, Kuroshio and Inter-trade.)
Draw the two waste streams on the contour maps with thicker arrows.
From what current is ... flow formed?
- Find the current of the Western Winds on the ocean map. Which oceans does it cross?
(VIDEO ABOUT THE CURRENT OF WESTERN WINDS)
Poem about the Current of the West Winds
Antarctica past Australia, America and Africa
Past all possible islands...
Everyone is sailing, my boats are sailing
Along the course of the Western winds.
I'll draw it on a worn map
This amazing route
In the blue of the vast expanse
Everyone is sailing, the boats are sailing.
Speaking about ocean currents, it seems to me that it will be very useful to know the peculiarities of the current of our native sea.
What sea am I talking about? (Black)
Which ocean basin does it belong to (Atlantic)
Help us learn about the currents of the Black Sea...
Black Sea Currents
The main current of the Black Sea is the Main Black Sea Current. It is directed counterclockwise and forms two noticeable rings (“Knipovich glasses”, this name is associated with the Russian hydrologist Nikolai Knipovich, who described this current). The current is very changeable. In the coastal waters of the Black Sea, vortices of the opposite direction are formed - anticyclonic currents.
Who likes to swim in the sea in summer? Why?
Water procedures very useful, but know that the sea is fraught with danger.... Please….
Secrets of the Black Sea
When swimming in the Black Sea, you should be aware of the existence of a local Black Sea current - “ draft». In the world, such a phenomenon is called RIP.
Most often, this current forms during a storm near sandy shores. The water flowing onto the shore does not return evenly, but in streams along the channels formed in the sandy bottom.
Getting caught in the jet's current is dangerous: it can be carried out to the open sea. To get out of the tug, you need to swim not straight to the shore, but at an angle to reduce the resistance of receding water.
V. Stage of consolidation of knowledge
We have practically dealt with the material. Let's remember what we wanted to know...
Have we received answers... But we don’t know everything. You can supplement your knowledge by completing homework, which let's write down in our diary.VI. Homework
1. Study &20., describe one of the currents according to the plan p.572.Creativeexerciseprepare a report on the currentEl Niño
Screening test
1.What has the greatest influence on the formation of currents in the ocean
A) constant winds
B) earthquakes
B) the gravity of the moon
2. What types of currents are there?
A) warm
B) cold
B) warm and cold
3. What currents begin at the equator
A) warm
B) cold
B) warm and cold
4. What are the influences of ocean currents?
A) on climate formation
B) on the formation of the ocean floor topography
B) on the rotation of the Earth
5.Name the largest cold current
A) Gulf Stream
B) Current of the Western winds
B) Peruvian Current
VII. Summing up results lesson A
Did you like the lesson?
What made an impression?
What did you like most?
I liked your work in class and I want to evaluate it
History of the discovery of surface currents
The first mentions of the existence of sea currents are found among ancient Greek scientists; Aristotle in his writings talks about currents in the Kerch, Bosporus and Dardanelles straits. And the Carthaginians had some idea about the Sargasso Sea.
It is known that in the Middle Ages the Norwegians discovered a sea route from northern Europe, first to Iceland, and then to Greenland and North America. On these voyages the Normans became familiar with sea currents. This is clear from the names they gave to noticeable places they encountered along the way, such as: Fr. Currents, Currents Bay, Currents Cape.
The Arabs sailed extensively in the Indian Ocean and established sea links with China, Mesopotamia and Egypt. They were familiar with monsoon currents.
The Portuguese, while moving south along the coast of Africa, became acquainted with the Guinea and Bengal Currents, and Vasco da Gama at the end of the 15th century, during his first voyage to India, noticed the Mozambique Current.
First observations of ocean currents
The first detailed observation of currents in the open ocean was made by Christopher Columbus during his first voyage to America, on September 13, 1492 in the region of 27° N. w. and 40° W. d. He noticed from the deviation of the lot, lowered deep into the water, that the ship was being carried by the current to the SW. Columbus's subsequent voyages introduced him even more to the North Equatorial Current and gave him the opportunity to suggest that the waters of the ocean along the equator move “together with the vault of heaven” to the west. On his fourth voyage (1502-1504), Columbus discovered a current running along the coast of Honduras.