home » Long 19th century Tectonic analysis of the geological map. Geostructures. structural floors. Formations. Analysis of the geological map and map of the tectonic structure Analysis of the tectonic map of the world

Tectonic analysis of the geological map. Geostructures. structural floors. Formations. Analysis of the geological map and map of the tectonic structure Analysis of the tectonic map of the world

Chapter III. TECTONICS

In tectonic terms, the studied area is located on the territory of a folded area.

According to the results of analyzes of the geological map, stratigraphic column, geological section, two structural stages can be distinguished: 1) D1-2bsk - C1sm; 2) I2 - K1sch.

As part of the first structural floor, two structural tiers can be distinguished. As part of the second floor, one structural tier with minor disagreements can be distinguished.

First floor.

lower structural layer.

The lower structural stage is composed mainly of volcanic rocks: volcanic breccias, tuffs, and other rocks of volcanic activity. From this we can conclude that during this period there was a maximum explosive stage of volcanic activity.

The rocks of this stage come to the surface in the northwestern, central, southwestern, and southeastern parts of the sheet. Separated in the volume of the Byskar series. The rocks of the lower tier are crumpled into sweetness.

The first fold is located in the southwest. The apparent width of the fold is about 1 km, and the length is 7 km. Stretching from west to east. The type of fold is anticlinal, according to the ratio of the axes - linear. The core includes rocks of the Byskar series. On the wings of the rocks of the middle and late Devonian system. The fold is asymmetric, because the angles of incidence are different on the wings.

The second fold is located in the central part of the sheet in the west. The rocks of the Byskar Series are also folded. The fold is approximately 1 km wide and 3 km long. The type of fold is anticlinal, according to the ratio of the axes - brachymorphic. The composition of the wings includes rocks of the middle and late Devonian system. The fold is asymmetric, because the angles of incidence are different on the wings.

The third fold is located in the northwestern part of the sheet in the west. The core of the fold contains rocks of the Byskar series. The apparent width of the fold is about 7 km, and the length is 13 km. The type of fold is anticlinal, according to the ratio of the axes - linear. On the wings are rocks of the middle and late Devonian system. The fold is asymmetric.

Upper structural layer.

The upper structural stage is composed of terrigenous-carbonate sediments. The stage was formed under continental conditions. The stage is represented in the volume of the Toltakovskaya, Saragashskaya, Beyskaya, Oidanovskaya, Kokhaiskaya, Tubinskaya, Bystryanskaya, Altai, Nadaltayskaya and Samokhvalskaya formations.

The deposits that make up this suite, mostly rocks, are exposed in the entire western part. There is volcanic activity in the Carboniferous period, which is represented by tuff sandstones. The rocks of this stage are crumpled into folds.

The fourth fold is located in the central western part of the leaf. The fold is anticline. The core contains rocks of the Toltakov Formation, which are brachymorphic in terms of the ratio of the axes. The fold is asymmetric and broken by a fault with a fault. The wings of the fold are rocks of the Middle Devonian system.

The fifth fold is located in the northern central part of the leaf. The fold is anticline, brachymorphic in relation to the axes. The core contains rocks of the Tol'takov Formation. On the wings are rocks of the middle and late Devonian system. The fold is asymmetric. The length of the fold is 1 km, the width is 1 km.

Second floor.

The structural stage is composed mainly of terrigenous sediments. This floor shows two small breaks in sedimentation in the eastern part. The deposits that make up this floor are distributed in the eastern part of the sheet. The rocks of this stage do not form folded structures.

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MOSCOW STATE UNIVERSITY

GEODESY AND CARTOGRAPHY

Department of Geography

Practical work No. 1

ANALYSIS OF PHYSICAL, TECTONIC AND GEOLOGICAL MAP

ZONE(100°-130° E)

I've done the work:

Student FKG KiG II-1b

Pashkin A.A.

Teacher:

Associate Professor of the Department of Geography Ph.D.

Kolesnikov Sergey Fyodorovich

Moscow 2014

Lithosphere and relief of the Earth

physical map

Geological map: Scale 1: 80,000,000

The structure of the earth's crust: Scale 1: 80,000,000

Climate map:

The area under consideration in this laboratory work is limited by the longitudes of 100°-130°E. On it there is a section of the terrain of Eurasia, which includes: Eastern Siberia, the Gobi Desert, Eastern Tibet, the Indochina Peninsula, the Indonesian Archipelago and Western Australia.

Research on physical map:

This area is located entirely in the Eastern Hemisphere between 100°-130°E. In the northern part: part of the Eurasian continent, in the southern Indian Ocean and Western Australia.

Relief:

It is very diverse, since there are quite mountainous areas here: the Central Siberian Plateau, part of Tibet and a rather flat area in Western Australia.

Geological structure:

It is represented by almost all rocks (mainly sedimentary)

In Eurasia, these are most often rocks of the Archean and Proterozoic groups of the Paleozoic, Jurassic, Triassic, Cretaceous systems of the Mesozoic group. Quaternary (in the south of Eurasia).

Australia: Quaternary, Paleogene-Neogene, Cretaceous, Permian system.

The structure of the earth's crust:

In this area, in the north, there is a boundary between the Eurasian and North American lithospheric plates. To the south, in two directions, there is the border of the Eurasian plate with the Philippine one. In the south is the boundary of the Indo-Australian and Antarctic plates.

In the north, we observe the divergence of lithospheric plates. Then south of the collision of plates. And then the divergence of lithospheric plates: Indo-Australian and Antarctic.

Indo-Australian plate. Almost all of Australia is a platform, most of which is plains. Tectonic activity is very slow, crystalline shields are formed. They are associated with minerals.

Climate: all climatic zones and climatic zones are presented here: from the Arctic to the equatorial zone. The continentality of the climate increases with distance from the sea.

Eurasia is rich in water resources; in the north and in mountainous areas, food is predominantly snow and glacial. In the west of Australia, opposite the shortage water resources and desert area.

The distribution of natural zones is mostly latitudinal and all natural areas from arctic deserts to equatorial forests. I am present in altitudinal zonation (mainly in Tibet).

Types of ionizing radiation, their physical nature and distribution features.

Question 27. Rationalistic philosophy of Descartes. The doctrine of substance

Individual socio-diagnostic card of a disabled person

2 Some historians believe that the February days of 1917, when the autocracy was overthrown with the participation of the Petrograd garrison with the use of armed struggle, became the beginning civil war Russia.

1 The Gospel of Matthew says: “No one can serve two masters, God and mammon: for either he will hate the one and love the other; or he will be zealous for one, and neglect the other. You cannot serve God and mammon." Matt., II, 24. (Mammon - wealth).

2 "Nature is not a temple, but a workshop and man is a worker in it." I.S. Turgenev, "Fathers and Sons". Phrase Bazarov.

3 Nature Temple and man part of the Temple. At the end of the 20th century, in the conditions of an ecological crisis leading to the death of the planet, local historical theory in countries Western Europe and North America replaced the liberal theory. growing fast political influence defenders environment- The Greens (Greenpeace).

4 At the end of the 20th century. from Eurocentric positions the idea of world globalism is affirmed - universal values

1 Eclecticism - (from the Greek eklektikos - choosing) a mechanical combination of heterogeneous, often opposite principles, views, etc.

2 V modern Russia public politicians, propagating historical experience in line with their ideas, “modernize” events, ignoring historical laws - time and space

Chapter 1 is written in line with the liberal direction of world-historical theory.

[i] The chapter is written in line with the liberal direction of the world-historical theory

The chapter is written in line with the liberal direction of the world-historical theory

[v] The chapter is written in line with the local-historical theory.

The chapter is written in line with the materialistic direction of the world-historical theory.

The chapter is written in line with the liberal direction of the world-historical theory

The chapter is written in line with the local-historical theory

The chapter is written in line with the local-historical theory.

ANALYSIS OF PHYSICAL, TECTONIC AND GEOLOGICAL MAP

ZONE(100°-130° E)

I've done the work:

Student FKG KiG II-1b

Pashkin A.A.

Teacher:

Associate Professor of the Department of Geography Ph.D.

Kolesnikov Sergey Fyodorovich

Moscow 2014

Lithosphere and relief of the Earth

physical map

Geological map: Scale 1: 80,000,000

The structure of the earth's crust: Scale 1: 80,000,000

Climate map:

The area under consideration in this laboratory work is limited by the longitudes of 100°-130°E. It contains a section of the Eurasian terrain that includes: Eastern Siberia, the Gobi Desert, the Eastern part of Tibet, the Indochina Peninsula, the Indonesian archipelago and the West of Australia.

Research on the physical map:

This area is located entirely in the Eastern Hemisphere between 100°-130°E. In the northern part: part of the Eurasian continent, in the southern Indian Ocean and Western Australia.

Relief:

It is very diverse, since there are quite mountainous areas here: the Central Siberian Plateau, part of Tibet and a rather flat area in Western Australia.

Geological structure:

It is represented by almost all rocks (mainly sedimentary)

In Eurasia, these are most often rocks of the Archean and Proterozoic groups of the Paleozoic, Jurassic, Triassic, Cretaceous systems of the Mesozoic group. Quaternary (in the south of Eurasia).

Australia: Quaternary, Paleogene-Neogene, Cretaceous, Permian system.

The structure of the earth's crust:

In the north, we observe the divergence of lithospheric plates. Then south of the collision of plates. And then the divergence of lithospheric plates: Indo-Australian and Antarctic.

Indo-Australian plate. Almost all of Australia is a platform, most of which is plains. Tectonic activity is very slow, crystalline shields are formed. They are associated with minerals.

Climate: all climatic zones and climatic zones are presented here: from the Arctic to the equatorial zone. The continentality of the climate increases with distance from the sea.

Eurasia is rich in water resources; in the north and in mountainous areas, food is predominantly snow and glacial. In the west of Australia, on the contrary, there is a lack of water resources and a desert area.

The distribution of natural zones is mostly latitudinal and all natural zones are represented, from arctic deserts to equatorial forests. I am present in altitudinal zonation (mainly in Tibet).

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Course work

in structural geology

Analysis of the geological map and map of the tectonic structure

Introduction

The course project sums up the study of the most important part of the course of structural geology, devoted to the forms of occurrence of rocks and methods of their representation on geological and tectonic maps and sections. It contributes to the development of the ability to freely read geological maps and use the collected material for a comprehensive theoretical analysis.

The main goal of the course work is to consolidate knowledge of structural geology and develop the acquired skills in analyzing a geological map and a map of a tectonic structure. The work also aims to teach how to use geological map data for a number of generalizations.

To analyze geological maps, it is necessary to be able to determine the age sequence of sedimentary, metamorphic and igneous rocks and establish the forms of their occurrence; identify and determine the types of unconformity surfaces, analyze their significance for the geological history of a given territory; identify the most characteristic rock formations and analyze their relationship with the tectonic structure and geological history; taking into account the age, composition and thickness of the distinguished stratigraphic units and their changes along strike, as well as on the basis of an analysis of the tectonic structure, establish the main structural elements of the area and give its tectonic zoning; be able to determine the age of igneous formations, as well as to determine which tectonic epoch the igneous complexes of the study area belong to; be able to describe the tectonic structure and outline the main stages of its formation; analyze the geological history of the area and draw the main conclusions about the patterns and relationships of the most important geological events, drawing on the knowledge gained from the courses of historical and structural geology.

When solving the questions posed, a number of methods are used: analysis of geological boundaries on the map, historical-geological and paleotectonic methods, analysis of the sequence of bedding, analysis of breaks and unconformities, method of studying facies, method of studying thicknesses, formational analysis and other methods.

When performing this course work, the northern part of the educational geological map No. 23, scale 1: 50000, 1984, was used.

1. Relief and river network

1.1 Relief

Two types of relief are distinguished in the studied territory - mid-mountain and low-mountain. The lowest elevations are 640 m, the highest are 1400 m. The maximum elevation is 760 m.

Low-mountain relief prevails, it occupies about 65 - 70% of the area of the region. The maximum elevation here is 360 m.

Alpine relief occupies 30-35% of the area of the entire territory, the maximum elevation is 400 m.

The relief is confined to outcrops of Neogene, Paleogene, Cretaceous and Jura rocks.

1.2 River network

The entire studied territory is occupied by the basin of the Belaya River, formed by two large tributaries that merge in the southwest of the region. The river is represented by the main channel and many tributaries. The direction of the river flow is to the northeast, the channel is slightly meandering.

The left tributaries have a flow direction to the south, the right - mainly to the north.

Of the large tributaries, one can also note the mountain stream Plishka and the Mutny stream, located in the eastern and northeastern parts of the region.

River floodplain width Belaya varies from 1 km to 100 m, and the floodplain area increases in the direction of the current, i.e. to the northeast. The floodplain in the Mutnoy creek valley is up to 1.5 km wide. The height of the terraces is up to 40 m. The floodplain and terraces are composed of alluvial pebbles and sands

1.3 Stratigraphy

The study area includes rocks of the Jurassic, Cretaceous, Paleogene and Neogene systems. The Jurassic, Cretaceous and Paleogene systems are composed of sedimentary strata, the Neogene system is represented by volcanic-sedimentary rocks.

Jurassic system.

The deposits of the Jurassic system are distributed over a small area in the western and northwestern parts of the study area.

Deposits of the Middle and Upper Jurassic are known.

Middle department.

The rocks of the middle section of the Jurassic system were distributed only in the so-called tectonic wedges, formed by large faults and located in the north-west of the territory.

The sequence is composed of red clays with the presence of limestone marls, has a thickness of more than 270 m.

Upper department.

Represented by deposits of the Tithonian stage.

Tithonian stage.

Deposits of the Tithonian stage of the Upper Jurassic are known within tectonic wedges, are more widespread than the rocks of the Middle Jurassic and are represented by red limestones. On the underlying rocks, the deposits of the Tithonian stage occur according to. The thickness of the entire thickness is 300 m.

Chalk system.

In the study area, the Cretaceous system is represented by two divisions - upper and lower. The deposits of this system are distributed in the northwest and southwest of the territory.

Lower section.

Represented by the Polyana Formation.

Polyanskaya suite.

The deposits of the Polyanskaya suite are not widely distributed, they are observed only in the north-west of the territory, mainly in the area of the settlement of Yuryevka and are represented by sandstones. The thickness of the thickness is more than 600 m.

The sequence rests on the underlying rocks unconformably; contact with the underlying Jurassic rocks is traced along a deep fault.

Upper department.

Represented by the Lyut retinue.

Lyut Formation

The deposits of the Lyutskaya suite stretch from the northwest to the southeast of the territory, crossing the river. Belaya near the settlement Yuryevka; a small outcrop of rocks is also observed in the southwest.

The sequence is composed of sandstones and rhythmically alternating marls and clays, its thickness is 280 m. On the underlying rocks of the Polyana suite, the Upper Cretaceous rocks occur in accordance with the Jurassic deposits, the contact is traced along the fault.

Paleogene system.

In the study area, the Paleogene system is represented by all three divisions. The rocks of this system are quite widespread; they are observed in the west and south-west of the region.

Lower section.

The deposits of the Lower Paleogene are most widely developed and are known mainly in the southwest of the territory. They are represented by rhythmically alternating siltstones and blue, red and green clays. The thickness of the entire stratum is 320 m.

Middle and upper divisions.

The undivided middle and upper sections are represented by the Lumshor Formation. The upper section is represented by the Petrovsky Formation.

Lumshor suite.

The deposits of the Lumshor Formation are quite widespread and stretch from west to south of the territory. They are represented by a rhythmic alternation of siltstones, mudstones and marls. The thickness of the sequence is 500 m. The contact with the underlying deposits of the Lower Paleogene is consistent.

Petrovsky retinue.

The deposits of the Petrovsky Formation stretch from the west to the south of the territory and are represented by black siliceous marls, mudstones and limestones. The thickness of the layer is 440 m.

Neogene system.

The Neogene system is represented by two divisions - the lower, Miocene, and the upper, Pliocene. Neogene deposits are widespread in the area and are represented by both sedimentary and volcanic-sedimentary rocks.

It is composed of strata of sedimentary rocks distributed in the north, east and southeast of the territory. There are three formations: Dusinskaya, Chernikskaya and Mikhailovskaya.

Dusinsky retinue.

The deposits of the Dusinskaya suite are not widely distributed and stretch along the southern margin of the Miocene deposits from the northwest to the southeast. Detrital rocks - conglomerates, gravelstones and sandstones, with a total thickness of more than 520 m. Contact with the underlying Mesozoic and Paleogene deposits can be traced along a large deep fault.

Chernik suite.

The deposits of the Chernikskaya suite are the most widely developed of all Miocene rocks. They occupy the entire area in the north, east and southeast of the district. Represented by gravelstones, sandstones and clays with interlayers of brown coals. The thickness of the entire stratum is 480 m.

Mikhailovskaya retinue.

The rocks of the Mikhailovskaya Formation are known in the northwest, northeast, and east of the study area. They are represented by conglomerates, sandstones and clays with interlayers of liparitic tuffs with a total thickness of 400 m. The contact with the underlying deposits of the Chernikskaya suite is consistent.

The upper section of the Neogene system is represented in the studied area by volcanic-sedimentary rocks. There are three subdivisions: lower, middle and upper. The lower and middle sections are undivided and are represented by deposits of the Bystrinskaya suite.

Bystrinsky suite.

Deposits of the Bysrinskaya suite are known mainly in the central part of the region. They are represented by a sequence of liparitic ignimbrites with a thickness of more than 700 m, lying with angular unconformity in the Miocene and Mesozoic deposits.

Middle Pliocene. ,

In the Middle Pliocene, sequences of dacitic lavas are known, distributed in small areas in the east and northeast of the territory and having a thickness of 85 m. Andesitic lavas are also known, common in the central and eastern parts of the region. Facies replacements by tuffs and tuff breccias occur in their thickness. The thickness of the strata is 250 m. The nature of the relationship with each other and with the underlying ones is an angular unconformity.

Upper Pliocene.

Deposits of the upper subdivision of the Pliocene are distributed in the east of the territory and stretch from south to north. They are represented by andesite-basalt lavas, the thickness of which is 80 m.

2. Intrusive formations

2.1 Pliocene intrusive formations

Intrusive formations are not widely developed in the study area and are represented by a single intrusive body located in the west of the territory. Its area is 0.75 km2, in plan it has a narrow, 250 m wide, elongated shape. Composed of granite-porphyry.

The size of the intrusive body is small; According to the structural features, it can be attributed to dikes.

The dike is dated to the Pliocene and has a secant contact with the Upper Cretaceous deposits, with the Upper Jurassic - contact along the fault. (Fig.1)

Rice. 1 Pliocene dyke composed of granite-porphyry

Vortex formations.

The rocks of the vent facies in the study area are represented by Middle Pliocene and Lower-Middle Pliocene formations, confined mainly to a large fault.

Vent formations of the Lower-Middle Pliocene.

Known in the south of the territory, in the area of the sources of the stream. Plishka. In total, there are 4 bodies in the area. In plan they have an elongated oval shape, their area is from 1 km2 to 0.7 km2. Composed of liparitic ignibrites, they belong to necks according to their structure.

They cut through the Pliocene deposits of the Bysrinskaya suite and are overlain by the Middle Pliocene strata.

Rice. 2 Vent formations of the Lower-Middle Pliocene.

Vent formations of the Middle Pliocene

4 bodies are known in the north-west of the territory, in the area south of the settlement of Yuryevka and in the north-east of the territory. They have an elongated oval shape.

The area of the smaller of them is 0.3 km2, the rest is about 0.75 km2. They are composed of dacites and, according to the features of their structure, belong to the necks. The bodies located in the center of the area break through the Mesozoic deposits and deposits of the Bysrinskaya suite. One of the bodies is overlain by andesite-basalts of the Middle Pliocene.

Rice. 3 Middle Pliocene vent formations

Rice. 4 Middle Pliocene vent formations

Tectonics.

According to the conditions of occurrence and magmatism in the structure of the region, the middle Alpine geosynclinal and late Alpine orogenic structural stages are distinguished.

Middle Alpine geosynclinal structural stage.

Includes deposits from the Middle Jurassic to the Petrovsky Formation of the Upper Paleogene, crumpled into linear folds. Developed in the southwest of the region.

In the structure of this structural stage, the following formations are distinguished: carbonate-terrigenous, including deposits of the Middle Jurassic (red clays, marls and limestones); formation of red limestones of the Tithonian stage of the Upper Jurassic; the formation of uneven-grained sandstones of the Polyanskaya suite of the Lower Cretaceous; two flysch carbonate-terrigenous formations, the lower of which includes deposits of the Lower Cretaceous Lyutskaya suite, and the upper one - the Petrovsky and Lumshorskaya formations of the Middle and Upper Paleogene (here, members of itmically alternating marls, siltstone clays, mudstones and limestones); flysch terrigenous formation of Lower Paleogene rocks (colorful clays and siltstones).

The rocks that make up the Middle Alpine geosynclinal stage are crumpled into linear folds. The axes of the folds stretch from the west and northwest to the south, crossing the river. Belaya in the area of the settlement Yuryevka and upstream.

According to the shape of the lock, the folds are rounded and comb-shaped, and the locks of the folds of older rocks (Cretaceous) have a comb-like shape. With respect to the axial surface to the horizon, the folds are inclined. The angles of inclination of the wings of the folds from to.

Among the clearly visible folds of the first order, 2 anticlinal and 1 synclinal folds stand out.

Synclinal folds.

The fold is located at the confluence of two tributaries in the Belaya River (Fig. 5), has a length of more than 7 km and a width of more than 2 km.

The wings of the fold are composed of rhythmically alternating carbonate-terrigenous rocks of the Lower and Middle Paleogene, in the core of the fold there is a flysch sequence composed of rhythmically alternating rocks of the Upper Paleogene Petrovsky Formation.

The axis of the fold stretches from west to south. The angles of inclination of the wings, and on the northern wing (the angles change accordingly from west to south) and on the southern wing.

The fold is round in shape of the castle, the hinge plunges in the southeast direction, rises in the northwest, forming a centriclinal closure.

Rice. 5 Synclinal fold

2.2 Anticlinal folds

One of them is located in the northwestern part of the territory, its axis stretches from the northwest to the south and, making a smooth bend, crosses the river. Belaya near the village of Yuryevka. The fold is over 10 km long and slightly over 1 km wide. Its wings are composed of rhythmically alternating carbonate and terrigenous rocks of the Upper Cretaceous Liutskaya suite, in the core - inequigranular sandstones of the Lower Cretaceous Polyanskaya suite.

The northern flank of the fold has a slope, the southern one.

The lock of the fold is ridge-shaped, the hinge either plunges in the direction to the northwest and southeast, forming two periclinal closures, then it rises. (Fig. 6)

Rice. 6 Cretaceous anticlinal fold

The second anticline fold is located in the southwest of the region. It is over 5 km long and up to 1 km wide.

The wings are composed of flysch Middle and Upper Paleogene sequences, in the core there is a rhythmic alternation of clays and siltstones of the Lower Paleogene age. The angles of inclination of the wings: at the southern wing, and at the northern one (the angles change in the northwest direction).

The lock of the fold is rounded; on immersion, the hinge forms a pereklinal closure. (Fig. 7)

Rice. 7 Anticlinal fold composed of Paleogene deposits

Among the folds of the second order, 3 synclinal folds can be distinguished, two of which are confined to the Cretaceous anticline fold, and one - to the Paleogene anticline fold.

There are two anticlinal folds of the second order - one is confined to the Cretaceous anticline fold of the first order, the second - to the Cretaceous deposits, the outcrop of which is observed in the south-west of the region.

2.3 Late Alpine orogenic structural stage

Includes deposits of the Miocene and Pliocene. According to the conditions of formation and features of the structure, it is divided into two sub-levels - upper and lower.

Lower structural subfloor.

Includes Miocene deposits folded into brachyform folds. Developed in the north and northeast of the region.

In the structure of the substage, the following formations are distinguished: the lower molasse, composed of conglomerates, gravelstones and sandstones of the Dusinsky suite of the Miocene; coal-bearing molasse, including deposits of the Chernikskaya suite and the upper molasse, including rocks of the Mikhailovskaya suite.

Tectonic structure of the region:

The rocks of this substage are crumpled into brachyform folds.

The limbs of the synclinal folds are composed of coarse clastic rocks of the Chernik and Dusinsk suites of the Miocene, with rocks of the Mikhailovskaya suite in the core.

The castle is rounded, the slope angles are gentle, from to, and the largest angles are noted near the southern flank of the fold, composed of rocks of the Dusinsky suite.

Upper structural subfloor.

Includes Pliocene deposits that make up a large volcanic edifice.

Liparitic ignimbrites of the Bysrinskaya Formation of the Lower-Middle Pliocene and dacitic lavas of the Middle Pliocene compose the terrestrial porphyry formation. Andesite-basaltic lavas, tuffs and tuff breccias of the Middle and Upper Pliocene make up the andesitic formation.

Tectonic structure of the region:

The volcanic edifice has a synclinal structure.

Lines of primary banding are directed towards the center at gentle angles no more.

Lower-Middle Pliocene deposits of the Bysrinskaya suite (liparitic ignimbrites) are confined to the intrusion of vent formations of the Lower-Middle Pliocene and form covers. They are distributed over a large area in the center of the region and cover all Mesozoic and Miocene deposits.

Dacitic lavas of the middle Pliocene compose two small shield volcanoes - one in the northwest of the territory, the other in the northeast. It is characterized by horizontal and inclined (up to) lines of primary banding.

Andesitic lavas of the middle Pliocene form flows with horizontal and inclined (up to) flow lines.

In smaller areas, andesite-basaltic lavas of the Upper Pliocene are common. They have sloping streamlines and stretch from south to north.

Breakdown violations.

On the territory of the study area, there are discontinuous faults of various types and age.

It is possible to distinguish inclined and vertical faults.

All inclined faults are confined to zones of linear folding. They have a longitudinal strike, a large extent, the angle of inclination of the displacer is about, the displacer itself has an inclination to the northwest.

Faults and reverse faults stand out among the faults.

Near reverse faults, the northwestern block is uplifted and composed of older rocks; near normal faults, the northwestern block is lowered, it is composed of younger rocks.

The time of formation of oblique faults is after the accumulation of the Upper Paleogene Petrovsky Formation, after linear folding, before the accumulation of the Miocene.

A large vertical normal fault stretches across the entire territory of the region from the northwest to the southeast, separating the orogenic and geosynclinal structural levels, and is overlapped in the southern and central parts by Pliocene volcanic-sedimentary formations. The northeastern block, composed of Miocene rocks, is subsided, while the southwestern block, composed of Jurassic, Cretaceous, and Paleogene deposits, is uplifted. Vertical normal faults are attached to this large fault in places, forming wedges along which Jurassic deposits are raised.

The age of the fault is after the accumulation of the Petrovsky Formation of the Late Paleogene, after linear folding, before the accumulation of Miocene strata. The fault is long-lived and remained tectonically active during the accumulation of Miocene deposits.

The latest faults are confined to the effusive strata of the Pliocene. They are located along the banks of the stream. Plishka, and are represented by vertical faults that form graben-like structures in pairs.

sedimentary mountainous tectonic geological

3. History of the geological development of the area

A geosynclinal trough existed on the territory of the studied area in the Middle Jurassic.

The sediments formed during this period testify to the existence of a marine basin of moderate depth with a remote coastline in this area, as evidenced by the terrigenous material present in the sequence.

In the Late Jurassic, the area of the sea basin increased, the coastline moved further away from the coast, as evidenced by the absence of terrigenous material in the thick limestone member. After that, there was an uplift and the associated regression of the sea.

In the early Cretaceous, the transgression of the sea began. The sea basin was shallow with a close coastline, as evidenced by a thick sequence of inequigranular sandstones formed due to the removal of clastic material from the nearby land.

Further, in the Late Cretaceous, the basin continues to deepen, and throughout both the Late Cretaceous and the entire Paleogene, carbonate and terrigenous rocks are deposited here, the rhythmic alternation of which indicates the possible action of turbidity flows.

After the accumulation of the Petrovsky Formation of the Late Paleogene, the uplift of the region occurred, the sea regression associated with it, after which the accumulated sediments were crushed into linear folds and faults were laid longitudinal and transverse to these folds. The Middle Alpine geosynclinal structural stage was formed. During the subsequent time, this territory remained dry land.

In the north-eastern territory of the region in the Miocene there was a shallow marine basin. The close location of the land led to the accumulation of coarse clastic material here, which formed molasse formations, interlayers of coal formed here in the Chernik time, which indicates an extremely close location of the land, and during the accumulation of the Mikhailovskaya Formation there was a small supply of volcanic material, which probably occurred as a result of the activity of the volcano located outside the study area.

After the accumulation of the Mikhailovskaya Formation, an uplift occurred, as a result of this, the sea regressed, and the accumulated sediments were crushed into brachiform sweets. The lower substage of the orogenic Late Alpine structural stage was formed.

In the Pliocene, deep-seated processes sharply intensified, which led to the introduction of Pliocene intrusions along large faults, with which the formation of tectonic wedges is associated, and, after that, to the beginning of the development of active volcanic activity, which continued throughout the Pliocene.

First, in the Lower and Middle Pliocene, magma was emplaced along a large fault, which formed vent formations, and the associated flows of liparitic ignimbrites were erupted.

In the Middle Pliocene, the intrusion of magma continued; vent formations and covers composed of dacitic lavas were associated with them.

Later intrusions of magma are associated with flows of andesites and andesite-basalts of the Middle and Upper Pliocene.

The tectonic activity of the region did not end there, several faults were formed, which formed graben-like structures.

Conclusion

The result of the analysis of the geological map was the writing of this term paper. A tectonic scheme and a diagram of the relief and river network were drawn up; sections, a block diagram and a structural-formational column were built.

In conclusion, it is worth mentioning the importance of doing this work, which consolidates all the material received over the previous two semesters.

Among the shortcomings, it should be noted that the deadlines for its implementation are too long. Perhaps they should be reduced to 1.5 months and set clear deadlines, which, of course, will only become an additional incentive for writing a course project as soon as possible.

List of used literature

1. A.E. Mikhailov. Structural Geology and Geological Mapping 2012.

2. Uspensky E.P., edited by Mikhailov A.E. Guidelines for term paper in Structural Geology and Geological Mapping 2009.

3. Benefit to laboratory work in structural geology, geomapping and remote methods 2010.

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Chapter III. TECTONICS

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