A distinctive feature of the earth's lithosphere, associated with the phenomenon of the global tectonics of our planet, is the presence of two types of crust: continental, which makes up continental masses, and oceanic. They differ in composition, structure, thickness and nature of the prevailing tectonic processes. An important role in the functioning of a single dynamic system, which is the Earth, belongs to the oceanic crust. To clarify this role, it is first necessary to turn to the consideration of its inherent features.

general characteristics

The oceanic type of crust forms the largest geological structure of the planet - the ocean bed. This crust has a small thickness - from 5 to 10 km (for comparison, the thickness of the continental-type crust is on average 35-45 km and can reach 70 km). It occupies about 70% of the total surface area of ​​the Earth, but in terms of mass it is almost four times inferior to the continental crust. The average density of rocks is close to 2.9 g/cm 3 , that is, higher than that of the continents (2.6-2.7 g/cm 3 ).

Unlike isolated blocks of the continental crust, the oceanic one is a single planetary structure, which, however, is not monolithic. The Earth's lithosphere is divided into a number of mobile plates formed by sections of the crust and the underlying upper mantle. The oceanic type of crust is present on all lithospheric plates; there are plates (for example, the Pacific or Nazca) that do not have continental masses.

Plate tectonics and crustal age

In the oceanic plate, such large structural elements as stable platforms - thalassocratons - and active mid-ocean ridges and deep-sea trenches are distinguished. Ridges are areas of spreading, or moving apart of plates and the formation of new crust, and trenches are subduction zones, or subduction of one plate under the edge of another, where the crust is destroyed. Thus, its continuous renewal takes place, as a result of which the age of the most ancient crust of this type does not exceed 160-170 million years, that is, it was formed in the Jurassic period.

On the other hand, it should be borne in mind that the oceanic type appeared on Earth earlier than the continental type (probably at the turn of the Catarcheans - Archeans, about 4 billion years ago), and is characterized by a much more primitive structure and composition.

What and how is the earth's crust under the oceans

Currently, there are usually three main layers of oceanic crust:

1. Sedimentary. It is formed mainly by carbonate rocks, partly by deep-water clays. Near the slopes of the continents, especially near the deltas of large rivers, there are also terrigenous sediments entering the ocean from land. In these areas, the thickness of precipitation can be several kilometers, but on average it is small - about 0.5 km. Precipitation is practically absent near mid-ocean ridges.
2. Basaltic. These are pillow-type lavas erupted, as a rule, under water. In addition, this layer includes a complex complex of dikes located below - special intrusions - of dolerite (that is, also basalt) composition. Its average thickness is 2-2.5 km.
3. Gabbro-serpentinite. It is composed of an intrusive analogue of basalt - gabbro, and in the lower part - serpentinites (metamorphosed ultrabasic rocks). The thickness of this layer, according to seismic data, reaches 5 km, and sometimes more. Its sole is separated from the upper mantle underlying the crust by a special interface - the Mohorovichic boundary.

The structure of the oceanic crust indicates that, in fact, this formation can, in a sense, be considered as a differentiated upper layer of the earth's mantle, consisting of its crystallized rocks, which is overlain from above by a thin layer of marine sediments.

"Conveyor" of the ocean floor

It is clear why there are few sedimentary rocks in this crust: they simply do not have time to accumulate in significant quantities. Growing from spreading zones in the areas of mid-ocean ridges due to the influx of hot mantle matter during the convection process, lithospheric plates, as it were, carry the oceanic crust further and further away from the place of formation. They are carried away by the horizontal section of the same slow but powerful convective current. In the subduction zone, the plate (and the crust in its composition) plunges back into the mantle as a cold part of this flow. At the same time, a significant part of the sediments is torn off, crushed, and ultimately goes to increase the crust of the continental type, that is, to reduce the area of ​​the oceans.

The oceanic type of crust is characterized by such an interesting property as strip magnetic anomalies. These alternating areas of direct and reverse magnetization of basalt are parallel to the spreading zone and are located symmetrically on both sides of it. They arise during the crystallization of basaltic lava, when it acquires remanent magnetization in accordance with the direction of the geomagnetic field in a particular epoch. Since it repeatedly experienced inversions, the direction of magnetization periodically changed to the opposite. This phenomenon is used in paleomagnetic geochronological dating, and half a century ago it served as one of the strongest arguments in favor of the correctness of the theory of plate tectonics.

Oceanic type of crust in the cycle of matter and in the heat balance of the Earth

Participating in the processes of lithospheric plate tectonics, the oceanic crust is an important element of long-term geological cycles. Such, for example, is the slow mantle-oceanic water cycle. The mantle contains a lot of water, and a considerable amount of it enters the ocean during the formation of the basalt layer of the young crust. But during its existence, the crust, in turn, is enriched due to the formation of the sedimentary layer with ocean water, a significant proportion of which, partially in a bound form, goes into the mantle during subduction. Similar cycles operate for other substances, for example, for carbon.

Plate tectonics play a key role in the Earth's energy balance, allowing heat to move slowly away from hot interiors and away from the surface. Moreover, it is known that in the entire geological history of the planet gave up to 90% of the heat through the thin crust under the oceans. If this mechanism did not work, the Earth would get rid of excess heat in a different way - perhaps, like Venus, where, as many scientists suggest, there was a global destruction of the crust when the superheated mantle substance broke through to the surface. Thus, the importance of the oceanic crust for the functioning of our planet in a regime suitable for the existence of life is also exceptionally great.

I can’t say that the school was a place of incredible discoveries for me, but there were really memorable moments in the lessons. For example, once in a literature class I was leafing through a geography textbook (don't ask), and somewhere in the middle I found a chapter on the differences between oceanic and continental crust. This information really surprised me. That's what I remember.

Oceanic crust: properties, layers, thickness

It is distributed, obviously, under the oceans. Although under some seas lies not even oceanic, but continental crust. This applies to those seas that are located above the continental shelf. Some underwater plateaus - microcontinents in the ocean are also composed of continental, and not oceanic crust.

But most of our planet is still covered by the oceanic crust. The average thickness of its layer is 6-8 km. Although there are places with a thickness of both 5 km and 15 km.

It consists of three main layers:

• sedimentary;
• basalt;
• gabbro-serpentinite.

Continental crust: properties, layers, thickness

It is also called continental. It occupies smaller areas than the oceanic one, but it is many times greater than it in thickness. On flat areas, the thickness varies from 25 to 45 km, and in the mountains it can reach 70 km!

It has from two to three layers (from bottom to top):

• lower ("basalt", also known as granulite-basite);
• upper (granite);
• "cover" from sedimentary rocks (not always happens).

Those parts of the crust where "sheath" rocks are absent are called shields.

The layered structure is somewhat reminiscent of the oceanic, but it is clear that their basis is completely different. The granite layer, which makes up most of the continental crust, is absent in the oceanic one as such.

It should be noted that the names of the layers are rather conditional. This is due to the difficulties of studying the composition of the earth's crust. The possibilities of drilling are limited, therefore, the deep layers were initially studied and are being studied not so much on the basis of "live" samples, but on the speed of seismic waves passing through them. Passing speed like granite? Let's call it granite. It is difficult to judge how "granite" the composition is.

A characteristic feature of the evolution of the Earth is the differentiation of matter, the expression of which is the shell structure of our planet. The lithosphere, hydrosphere, atmosphere, biosphere form the main shells of the Earth, differing in chemical composition, power and state of matter.

The internal structure of the Earth

The chemical composition of the Earth(Fig. 1) is similar to the composition of other terrestrial planets, such as Venus or Mars.

In general, elements such as iron, oxygen, silicon, magnesium, and nickel predominate. The content of light elements is low. The average density of the Earth's matter is 5.5 g/cm 3 .

There is very little reliable data on the internal structure of the Earth. Consider Fig. 2. It depicts the internal structure of the Earth. The earth consists of the earth's crust, mantle and core.

Rice. 1. The chemical composition of the Earth

Rice. 2. The internal structure of the Earth

Nucleus

Nucleus(Fig. 3) is located in the center of the Earth, its radius is about 3.5 thousand km. The core temperature reaches 10,000 K, i.e., it is higher than the temperature of the outer layers of the Sun, and its density is 13 g / cm 3 (compare: water - 1 g / cm 3). The core presumably consists of alloys of iron and nickel.

The outer core of the Earth has a greater power than the inner core (radius 2200 km) and is in a liquid (molten) state. The inner core is under enormous pressure. The substances that compose it are in a solid state.

Mantle

Mantle- the geosphere of the Earth, which surrounds the core and makes up 83% of the volume of our planet (see Fig. 3). Its lower boundary is located at a depth of 2900 km. The mantle is divided into a less dense and plastic upper part (800-900 km), from which magma(translated from Greek means "thick ointment"; this is the molten substance of the earth's interior - a mixture of chemical compounds and elements, including gases, in a special semi-liquid state); and a crystalline lower one, about 2000 km thick.

Rice. 3. Structure of the Earth: core, mantle and earth's crust

Earth's crust

Earth's crust - the outer shell of the lithosphere (see Fig. 3). Its density is approximately two times less than the average density of the Earth - 3 g/cm 3 .

Separates the earth's crust from the mantle Mohorovicic border(it is often called the Moho boundary), characterized by a sharp increase in seismic wave velocities. It was installed in 1909 by a Croatian scientist Andrey Mohorovichich (1857- 1936).

Since the processes occurring in the uppermost part of the mantle affect the movement of matter in the earth's crust, they are combined under the general name lithosphere(stone shell). The thickness of the lithosphere varies from 50 to 200 km.

Below the lithosphere is asthenosphere- less hard and less viscous, but more plastic shell with a temperature of 1200 °C. It can cross the Moho boundary, penetrating into the earth's crust. The asthenosphere is the source of volcanism. It contains pockets of molten magma, which is introduced into the earth's crust or poured onto the earth's surface.

The composition and structure of the earth's crust

Compared to the mantle and core, the earth's crust is a very thin, hard, and brittle layer. It is composed of a lighter substance, which currently contains about 90 natural chemical elements. These elements are not equally represented in the earth's crust. Seven elements—oxygen, aluminum, iron, calcium, sodium, potassium, and magnesium—account for 98% of the mass of the earth's crust (see Figure 5).

Peculiar combinations of chemical elements form various rocks and minerals. The oldest of them are at least 4.5 billion years old.

Rice. 4. The structure of the earth's crust

Rice. 5. The composition of the earth's crust

Mineral is a relatively homogeneous in its composition and properties of a natural body, formed both in the depths and on the surface of the lithosphere. Examples of minerals are diamond, quartz, gypsum, talc, etc. (You will find a description of the physical properties of various minerals in Appendix 2.) The composition of the Earth's minerals is shown in fig. 6.

Rice. 6. General mineral composition of the Earth

Rocks are made up of minerals. They can be composed of one or more minerals.

Sedimentary rocks - clay, limestone, chalk, sandstone, etc. - formed by the precipitation of substances in the aquatic environment and on land. They lie in layers. Geologists call them pages of the history of the Earth, because they can learn about the natural conditions that existed on our planet in ancient times.

Among sedimentary rocks, organogenic and inorganic (detrital and chemogenic) are distinguished.

Organogenic rocks are formed as a result of the accumulation of the remains of animals and plants.

Clastic rocks are formed as a result of weathering, the formation of destruction products of previously formed rocks with the help of water, ice or wind (Table 1).

Table 1. Clastic rocks depending on the size of the fragments

Breed name	Size of bummer con (particles)
	Over 50 cm
	5 mm - 1 cm
	1 mm - 5 mm
Sand and sandstones	0.005 mm - 1 mm
	Less than 0.005mm

Chemogenic rocks are formed as a result of sedimentation from the waters of the seas and lakes of substances dissolved in them.

In the thickness of the earth's crust, magma forms igneous rocks(Fig. 7), such as granite and basalt.

Sedimentary and igneous rocks, when immersed to great depths under the influence of pressure and high temperatures, undergo significant changes, turning into metamorphic rocks. So, for example, limestone turns into marble, quartz sandstone into quartzite.

Three layers are distinguished in the structure of the earth's crust: sedimentary, "granite", "basalt".

Sedimentary layer(see Fig. 8) is formed mainly by sedimentary rocks. Clays and shales predominate here, sandy, carbonate and volcanic rocks are widely represented. In the sedimentary layer there are deposits of such mineral, like coal, gas, oil. All of them are of organic origin. For example, coal is a product of the transformation of plants of ancient times. The thickness of the sedimentary layer varies widely - from complete absence in some areas of land to 20-25 km in deep depressions.

Rice. 7. Classification of rocks by origin

"Granite" layer consists of metamorphic and igneous rocks similar in their properties to granite. The most common here are gneisses, granites, crystalline schists, etc. The granite layer is not found everywhere, but on the continents, where it is well expressed, its maximum thickness can reach several tens of kilometers.

"Basalt" layer formed by rocks close to basalts. These are metamorphosed igneous rocks, denser than the rocks of the "granite" layer.

The thickness and vertical structure of the earth's crust are different. There are several types of the earth's crust (Fig. 8). According to the simplest classification, oceanic and continental crust are distinguished.

Continental and oceanic crust are different in thickness. Thus, the maximum thickness of the earth's crust is observed under mountain systems. It is about 70 km. Under the plains, the thickness of the earth's crust is 30-40 km, and under the oceans it is the thinnest - only 5-10 km.

Rice. 8. Types of the earth's crust: 1 - water; 2 - sedimentary layer; 3 - interbedding of sedimentary rocks and basalts; 4, basalts and crystalline ultramafic rocks; 5, granite-metamorphic layer; 6 - granulite-mafic layer; 7 - normal mantle; 8 - decompressed mantle

The difference between the continental and oceanic crust in terms of rock composition is manifested in the absence of a granite layer in the oceanic crust. Yes, and the basalt layer of the oceanic crust is very peculiar. In terms of rock composition, it differs from the analogous layer of the continental crust.

The boundary of land and ocean (zero mark) does not fix the transition of the continental crust into the oceanic one. The replacement of the continental crust by oceanic occurs in the ocean approximately at a depth of 2450 m.

Rice. 9. The structure of the continental and oceanic crust

There are also transitional types of the earth's crust - suboceanic and subcontinental.

Suboceanic crust located along the continental slopes and foothills, can be found in the marginal and Mediterranean seas. It is a continental crust up to 15-20 km thick.

subcontinental crust located, for example, on volcanic island arcs.

Based on materials seismic sounding - seismic wave velocity - we get data on the deep structure of the earth's crust. Thus, the Kola superdeep well, which for the first time made it possible to see rock samples from a depth of more than 12 km, brought a lot of unexpected things. It was assumed that at a depth of 7 km, a “basalt” layer should begin. In reality, however, it was not discovered, and gneisses predominated among the rocks.

Change in the temperature of the earth's crust with depth. The surface layer of the earth's crust has a temperature determined by solar heat. it heliometric layer(from the Greek Helio - the Sun), experiencing seasonal temperature fluctuations. Its average thickness is about 30 m.

Below is an even thinner layer, the characteristic feature of which is a constant temperature corresponding to the average annual temperature of the observation site. The depth of this layer increases in the continental climate.

Even deeper in the earth's crust, a geothermal layer is distinguished, the temperature of which is determined by the internal heat of the Earth and increases with depth.

The increase in temperature occurs mainly due to the decay of radioactive elements that make up the rocks, primarily radium and uranium.

The magnitude of the increase in temperature of rocks with depth is called geothermal gradient. It varies over a fairly wide range - from 0.1 to 0.01 ° C / m - and depends on the composition of the rocks, the conditions of their occurrence and a number of other factors. Under the oceans, the temperature rises faster with depth than on the continents. On average, with every 100 m of depth it becomes warmer by 3 °C.

The reciprocal of the geothermal gradient is called geothermal step. It is measured in m/°C.

The heat of the earth's crust is an important energy source.

The part of the earth's crust extending to the depths available for geological study forms bowels of the earth. The bowels of the Earth require special protection and reasonable use.

- limited to the surface of the land or the bottom of the oceans. It also has a geophysical boundary, which is the section Moho. The boundary is characterized by the fact that seismic wave velocities sharply increase here. It was installed in $1909 by a Croatian scientist A. Mohorovic ($1857$-$1936$).

The earth's crust is made up sedimentary, igneous and metamorphic rocks, and in terms of composition it stands out three layers. Rocks of sedimentary origin, the destroyed material of which was redeposited in the lower layers and formed sedimentary layer the earth's crust, covers the entire surface of the planet. In some places it is very thin and may be interrupted. In other places, it reaches a thickness of several kilometers. Sedimentary are clay, limestone, chalk, sandstone, etc. They are formed by sedimentation of substances in water and on land, they usually lie in layers. From sedimentary rocks, you can learn about the natural conditions that existed on the planet, so geologists call them pages of the history of the Earth. Sedimentary rocks are subdivided into organogenic, which are formed by the accumulation of the remains of animals and plants and non-organogenic, which are further subdivided into clastic and chemogenic.

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clastic rocks are the product of weathering, and chemogenic- the result of the precipitation of substances dissolved in the water of the seas and lakes.

Igneous rocks make up granite layer of the earth's crust. These rocks were formed as a result of solidification of molten magma. On the continents, the thickness of this layer is $15$-$20$ km, it is completely absent or very much reduced under the oceans.

Igneous matter, but poor in silica composes basaltic layer with a high specific gravity. This layer is well developed at the base of the earth's crust of all regions of the planet.

The vertical structure and thickness of the earth's crust are different, therefore, several types of it are distinguished. According to a simple classification, there is oceanic and continental Earth's crust.

continental crust

Continental or continental crust is different from oceanic crust thickness and device. The continental crust is located under the continents, but its edge does not coincide with the coastline. From the point of view of geology, the real continent is the entire area of ​​the continuous continental crust. Then it turns out that the geological continents are larger than the geographical continents. Coastal areas of the continents, called shelf- these are parts of the continents temporarily flooded by the sea. Such seas as the White, East Siberian, Azov Seas are located on the continental shelf.

There are three layers in the continental crust:

• The upper layer is sedimentary;
• The middle layer is granite;
• The bottom layer is basalt.

Under young mountains this type of crust has a thickness of $75$ km, under plains up to $45$ km, and under island arcs up to $25$ km. The upper sedimentary layer of the continental crust is formed by clay deposits and carbonates of shallow marine basins and coarse clastic facies in foredeeps, as well as on the passive margins of Atlantic-type continents.

Magma invading the cracks in the earth's crust formed granite layer which contains silica, aluminum and other minerals. The thickness of the granite layer can be up to $25$ km. This layer is very ancient and has a solid age of $3 billion years. Between the granite and basalt layers, at a depth of up to $20$ km, there is a boundary Conrad. It is characterized by the fact that the propagation velocity of longitudinal seismic waves here increases by $0.5$ km/sec.

Formation basalt layer occurred as a result of outpouring of basalt lavas onto the land surface in zones of intraplate magmatism. Basalts contain more iron, magnesium and calcium, so they are heavier than granite. Within this layer, the propagation velocity of longitudinal seismic waves is from $6.5$-$7.3$ km/sec. Where the boundary becomes blurred, the velocity of longitudinal seismic waves increases gradually.

Remark 2

The total mass of the earth's crust of the mass of the entire planet is only $0.473$%.

One of the first tasks associated with determining the composition upper continental bark, young science undertook to solve geochemistry. Since the bark is made up of a wide variety of rocks, this task was very difficult. Even in one geological body, the composition of rocks can vary greatly, and different types of rocks can be common in different areas. Based on this, the task was to determine the general, average composition that part of the earth's crust that comes to the surface on the continents. This first estimate of the composition of the upper crust was made by Clark. He worked as an employee of the US Geological Survey and was engaged in the chemical analysis of rocks. In the course of many years of analytical work, he managed to summarize the results and calculate the average composition of the rocks, which was close to to granite. Work Clark was subjected to harsh criticism and had opponents.

The second attempt to determine the average composition of the earth's crust was made by W. Goldschmidt. He suggested that moving along the continental crust glacier, can scrape and mix exposed rocks that would be deposited during glacial erosion. They will then reflect the composition of the middle continental crust. Having analyzed the composition of banded clays, which were deposited during the last glaciation in Baltic Sea, he got a result close to the result Clark. Different methods gave the same scores. Geochemical methods were confirmed. These issues have been addressed, and the assessments received wide recognition. Vinogradov, Yaroshevsky, Ronov and others.

oceanic crust

oceanic crust located where the depth of the sea is more than $ 4 $ km, which means that it does not occupy the entire space of the oceans. The rest of the area is covered with bark intermediate type. The oceanic-type crust is not organized in the same way as the continental crust, although it is also divided into layers. It has almost no granite layer, while the sedimentary one is very thin and has a thickness of less than $1$ km. The second layer is still unknown, so it is simply called second layer. Bottom third layer basaltic. The basalt layers of the continental and oceanic crust are similar in seismic wave velocities. The basalt layer in the oceanic crust prevails. According to the theory of plate tectonics, the oceanic crust is constantly formed in the mid-ocean ridges, then it moves away from them and in areas subduction absorbed into the mantle. This indicates that the oceanic crust is relatively young. The largest number of subduction zones is typical for Pacific Ocean where powerful seaquakes are associated with them.

Definition 1

Subduction- this is the lowering of rock from the edge of one tectonic plate into a semi-molten asthenosphere

In the case when the upper plate is a continental plate, and the lower one is an oceanic one, ocean trenches.
Its thickness in different geographical areas varies from $5$-$7$ km. Over time, the thickness of the oceanic crust practically does not change. This is due to the amount of melt released from the mantle in the mid-ocean ridges and the thickness of the sedimentary layer at the bottom of the oceans and seas.

Sedimentary layer oceanic crust is small and rarely exceeds a thickness of $0.5$ km. It consists of sand, deposits of animal remains and precipitated minerals. Carbonate rocks of the lower part are not found at great depths, and at a depth of more than $4.5$ km, carbonate rocks are replaced by red deep-water clays and siliceous silts.

Basalt lavas of tholeiite composition formed in the upper part basalt layer, and below lies dike complex.

Definition 2

dikes- these are channels through which basalt lava flows to the surface

Basalt layer in zones subduction turns into ecgoliths, which submerge in depth because they have a high density of surrounding mantle rocks. Their mass is about $7$% of the mass of the entire Earth's mantle. Within the basalt layer, the velocity of longitudinal seismic waves is $6.5$-$7$ km/sec.

The average age of the oceanic crust is $100$ million years, while its oldest sections are $156$ million years old and are located in the basin Pijafeta in the Pacific Ocean. The oceanic crust is concentrated not only within the World Ocean floor, it can also be in closed basins, for example, the northern basin of the Caspian Sea. Oceanic the earth's crust has a total area of ​​$306$ million sq. km.

Line UMK "Classical geography" (5-9)

Geography

The internal structure of the Earth. A world of amazing secrets in one article

We often look at the sky and think about how the cosmos works. We read about astronauts and satellites. And it seems that all the mysteries unsolved by man are there - outside the globe. In fact, we live on a planet full of amazing mysteries. And we dream about space, without thinking about how complex and interesting our Earth is.

The internal structure of the Earth

Planet Earth is made up of three main layers: earth's crust, robes and nuclei. You can compare the globe to an egg. Then the eggshell will be the earth's crust, the egg white will be the mantle, and the yolk will be the core.

The upper part of the earth is called lithosphere(translated from Greek "stone ball"). This is a hard shell of the globe, which includes the earth's crust and the upper part of the mantle.

The textbook is addressed to students of the 6th grade and is included in the TMC "Classical Geography". Modern design, a variety of questions and tasks, the possibility of parallel work with the electronic form of the textbook contribute to the effective assimilation of educational material. The textbook complies with the Federal State Educational Standard for Basic General Education.

Earth's crust

The earth's crust is a stone shell that covers the entire surface of our planet. Under the oceans, its thickness does not exceed 15 kilometers, and on the continents - 75. If we return to the egg analogy, then the earth's crust in relation to the entire planet is thinner than an eggshell. This layer of the Earth accounts for only 5% of the volume and less than 1% of the mass of the entire planet.

In the composition of the earth's crust, scientists have found oxides of silicon, alkali metals, aluminum and iron. The crust under the oceans consists of sedimentary and basalt layers, it is heavier than the continental (mainland). While the shell covering the continental part of the planet has a more complex structure.

There are three layers of the continental crust:

sedimentary (10-15 km mostly sedimentary rocks);

granite (5-15 km of metamorphic rocks, similar in properties to granite);

basaltic (10-35 km of igneous rocks).

Mantle

Under the earth's crust is the mantle ( "veil, cloak"). This layer is up to 2900 km thick. It accounts for 83% of the total volume of the planet and almost 70% of the mass. The mantle consists of heavy minerals rich in iron and magnesium. This layer has a temperature of over 2000°C. However, much of the material in the mantle retains its solid crystalline state due to the enormous pressure. At a depth of 50 to 200 km, there is a mobile upper layer of the mantle. It's called the asthenosphere "powerless sphere"). The asthenosphere is very plastic, it is because of it that volcanic eruptions and the formation of mineral deposits occur. The thickness of the asthenosphere reaches from 100 to 250 km. The substance that penetrates from the asthenosphere into the earth's crust and sometimes pours out to the surface is called magma. ("mush, thick ointment"). When magma solidifies on the Earth's surface, it turns into lava.

Nucleus

Under the mantle, as if under a veil, is the earth's core. It is located 2900 km from the surface of the planet. The core has the shape of a ball with a radius of about 3500 km. Since people have not yet managed to get to the core of the Earth, scientists are guessing about its composition. Presumably, the core consists of iron with an admixture of other elements. This is the densest and heaviest part of the planet. It accounts for only 15% of the volume of the Earth and as much as 35% of the mass.

It is believed that the core consists of two layers - a solid inner core (with a radius of about 1300 km) and a liquid outer core (about 2200 km). The inner core seems to be floating in the outer liquid layer. Because of this smooth movement around the Earth, its magnetic field is formed (it is it that protects the planet from dangerous cosmic radiation, and the compass needle reacts to it). The core is the hottest part of our planet. For a long time it was believed that its temperature reaches, presumably, 4000-5000°C. However, in 2013, scientists conducted a laboratory experiment in which they determined the melting point of iron, which is probably part of the Earth's inner core. So it turned out that the temperature between the inner solid and outer liquid core is equal to the temperature of the surface of the Sun, that is, about 6000 ° C.

The structure of our planet is one of the many mysteries unsolved by mankind. Most of the information about it was obtained by indirect methods; not a single scientist has yet been able to extract samples of the earth's core. The study of the structure and composition of the Earth is still fraught with insurmountable difficulties, but researchers do not give up and are looking for new ways to get reliable information about the planet Earth.

When studying the topic "Internal Structure of the Earth", students may have difficulty remembering the names and order of the layers of the globe. Latin names will be much easier to remember if the children create their own model of the Earth. You can invite students to make a model of the globe from plasticine or talk about its structure using fruits as an example (peel - earth's crust, pulp - mantle, bone - core) and objects that have a similar structure. The textbook by O.A. Klimanova will help in conducting the lesson, where you will find colorful illustrations and detailed information on the topic.