How long did the ice age last on earth. Ice ages in the history of the earth

Ecology

The ice ages that have taken place more than once on our planet have always been covered in a mass of mysteries. We know that they shrouded entire continents in cold, turning them into uninhabited tundra.

Also known about 11 such periods, and all of them took place with regular constancy. However, we still don't know much about them. We invite you to get acquainted with the most interesting facts about the ice ages of our past.

giant animals

By the time the last ice age arrived, evolution had already mammals appeared. Animals that could survive in harsh climatic conditions were quite large, their bodies were covered with a thick layer of fur.

Scientists have named these creatures "megafauna", which was able to survive at low temperatures in areas covered with ice, for example, in the region of modern Tibet. Smaller animals couldn't adjust to new conditions of glaciation and perished.

Herbivorous representatives of the megafauna have learned to find their food even under layers of ice and have been able to adapt to the environment in different ways: for example, rhinos ice age had spatulate horns, with the help of which they dug up snowdrifts.

Predatory animals, for example, saber-toothed cats, giant short-faced bears and dire wolves, perfectly survived in the new conditions. Although their prey could sometimes fight back due to their large size, it was in abundance.

ice age people

Although modern man Homo sapiens could not boast at that time of large size and wool, he was able to survive in the cold tundra of the ice ages for many millennia.

Living conditions were harsh, but people were resourceful. For example, 15 thousand years ago they lived in tribes that were engaged in hunting and gathering, built original dwellings from mammoth bones, and sewed warm clothes from animal skins. When food was plentiful, they stocked up in the permafrost - natural freezer.

Mostly for hunting, such tools as stone knives and arrows were used. To catch and kill the large animals of the Ice Age, it was necessary to use special traps. When the beast fell into such traps, a group of people attacked him and beat him to death.

Little Ice Age

Between major ice ages, there were sometimes small periods. It cannot be said that they were destructive, but they also caused famine, disease due to crop failure, and other problems.

The most recent of the Little Ice Ages began around 12th-14th centuries. The most difficult time can be called the period from 1500 to 1850. At this time in the Northern Hemisphere, a fairly low temperature was observed.

In Europe, it was common when the seas froze, and in mountainous areas, for example, in the territory of modern Switzerland, the snow did not melt even in summer. Cold weather affected every aspect of life and culture. Probably, the Middle Ages remained in history, as "Time of Troubles" also because the planet was dominated by a small ice age.

periods of warming

Some ice ages actually turned out to be quite warm. Despite the fact that the surface of the earth was shrouded in ice, the weather was relatively warm.

Sometimes a sufficiently large amount of carbon dioxide accumulated in the atmosphere of the planet, which is the cause of the appearance greenhouse effect when heat is trapped in the atmosphere and warms the planet. In this case, the ice continues to form and reflect the sun's rays back into space.

According to experts, this phenomenon led to the formation giant desert with ice on the surface but quite warm weather.

When will the next ice age start?

The theory that ice ages occur on our planet at regular intervals goes against theories about global warming. There's no doubt about what's happening today global warming which may help prevent the next ice age.

Human activity leads to the release of carbon dioxide, which is largely responsible for the problem of global warming. However, this gas has another strange side effect. According to researchers from University of Cambridge, the release of CO2 could stop the next ice age.

According to the planetary cycle of our planet, the next ice age should come soon, but it can take place only if the level of carbon dioxide in the atmosphere will be relatively low. However, CO2 levels are currently so high that no ice age is out of the question anytime soon.

Even if humans abruptly stop emitting carbon dioxide into the atmosphere (which is unlikely), the existing amount will be enough to prevent the onset of an ice age. at least another thousand years.

Plants of the Ice Age

The easiest way to live in the Ice Age predators: they could always find food for themselves. But what do herbivores actually eat?

It turns out that there was enough food for these animals. During the ice ages on the planet many plants grew that could survive in harsh conditions. The steppe area was covered with shrubs and grass, which fed mammoths and other herbivores.

Larger plants could also be found in great abundance: for example, firs and pines. Found in warmer regions birches and willows. That is, the climate by and large in many modern southern regions resembled the one that exists today in Siberia.

However, the plants of the Ice Age were somewhat different from modern ones. Of course, with the onset of cold weather many plants died. If the plant was not able to adapt to the new climate, it had two options: either move to more southern zones, or die.

For example, the present-day state of Victoria in southern Australia had the richest variety of plant species on the planet until the Ice Age most of the species died.

Cause of the Ice Age in the Himalayas?

It turns out that the Himalayas, the highest mountain system of our planet, directly related with the onset of the ice age.

40-50 million years ago the land masses where China and India are today collided to form the highest mountains. As a result of the collision, huge volumes of "fresh" rocks from the bowels of the Earth were exposed.

These rocks eroded, and as a result of chemical reactions, carbon dioxide began to be displaced from the atmosphere. The climate on the planet began to become colder, the ice age began.

snowball earth

During different ice ages, our planet was mostly shrouded in ice and snow. only partially. Even during the most severe ice age, ice covered only one third of the globe.

However, there is a hypothesis that at certain periods the Earth was still completely covered in snow, which made her look like a giant snowball. Life still managed to survive thanks to the rare islands with relatively little ice and with enough light for plant photosynthesis.

According to this theory, our planet turned into a snowball at least once, more precisely 716 million years ago.

Garden of Eden

Some scientists are convinced that garden of eden described in the Bible actually existed. It is believed that he was in Africa, and it is thanks to him that our distant ancestors survived the ice age.

About 200 thousand years ago came a severe ice age, which put an end to many forms of life. Fortunately, a small group of people were able to survive the period of severe cold. These people moved to the area where South Africa is today.

Despite the fact that almost the entire planet was covered with ice, this area remained ice-free. A large number of living beings lived here. The soils of this area were rich in nutrients, so there was abundance of plants. Caves created by nature were used by people and animals as shelters. For living beings, it was a real paradise.

According to some scientists, in the "Garden of Eden" lived no more than a hundred people, which is why humans do not have as much genetic diversity as most other species. However, this theory has not found scientific evidence.

In the history of the Earth, there were long periods when the entire planet was warm - from the equator to the poles. But there were also times so cold that glaciations reached those regions that currently belong to the temperate zones. Most likely, the change of these periods was cyclical. During warmer times, there could be relatively little ice, and it was only in the polar regions or on the tops of mountains. An important feature of ice ages is that they change the nature of the earth's surface: each glaciation affects the appearance of the Earth. By themselves, these changes may be small and insignificant, but they are permanent.

History of Ice Ages

We do not know exactly how many ice ages there have been throughout the history of the Earth. We know of at least five, possibly seven, ice ages, starting with the Precambrian, in particular: 700 million years ago, 450 million years ago (Ordovician), 300 million years ago - Permo-Carboniferous glaciation, one of the largest ice ages, affecting the southern continents. The southern continents refer to the so-called Gondwana, an ancient supercontinent that included Antarctica, Australia, South America, India and Africa.

The most recent glaciation refers to the period in which we live. The Quaternary period of the Cenozoic era began about 2.5 million years ago, when the glaciers of the Northern Hemisphere reached the sea. But the first signs of this glaciation date back 50 million years ago in Antarctica.

The structure of each ice age is periodic: there are relatively short warm epochs, and there are longer periods of icing. Naturally, cold periods are not the result of glaciation alone. Glaciation is the most obvious consequence of cold periods. However, there are quite long intervals that are very cold, despite the absence of glaciations. Today, examples of such regions are Alaska or Siberia, where it is very cold in winter, but there is no glaciation, because there is not enough rainfall to provide enough water for the formation of glaciers.

Discovery of ice ages

The fact that there are ice ages on Earth has been known to us since the middle of the 19th century. Among the many names associated with the discovery of this phenomenon, the first is usually the name of Louis Agassiz, a Swiss geologist who lived in the middle of the 19th century. He studied the glaciers of the Alps and realized that they were once much more extensive than they are today. It wasn't just him who noticed. In particular, Jean de Charpentier, another Swiss, also noted this fact.

It is not surprising that these discoveries were made mainly in Switzerland, since there are still glaciers in the Alps, although they are melting quite quickly. It is easy to see that once the glaciers were much larger - just look at the Swiss landscape, the troughs (glacial valleys) and so on. However, it was Agassiz who first put forward this theory in 1840, publishing it in the book "Étude sur les glaciers", and later, in 1844, he developed this idea in the book "Système glaciare". Despite initial skepticism, over time, people began to realize that this was indeed true.

With the advent of geological mapping, especially in Northern Europe, it became clear that earlier glaciers had a huge scale. Then there were extensive discussions about how this information relates to the Flood, because there was a conflict between geological evidence and biblical teachings. Initially, glacial deposits were called deluvial because they were considered evidence of the Flood. Only later it became known that such an explanation is not suitable: these deposits were evidence of a cold climate and extensive glaciation. By the beginning of the 20th century, it became clear that there were many glaciations, and not just one, and from that moment this area of ​​​​science began to develop.

Ice Age Research

Known geological evidence of ice ages. The main evidence for glaciations comes from the characteristic deposits formed by glaciers. They are preserved in the geological section in the form of thick ordered layers of special deposits (sediments) - diamicton. These are simply glacial accumulations, but they include not only deposits of a glacier, but also deposits of melt water formed by its flows, glacial lakes or glaciers moving into the sea.

There are several forms of glacial lakes. Their main difference is that they are a water body enclosed by ice. For example, if we have a glacier that rises into a river valley, then it blocks the valley like a cork in a bottle. Naturally, when ice blocks a valley, the river will still flow and the water level will rise until it overflows. Thus, a glacial lake is formed through direct contact with ice. There are certain deposits that are contained in such lakes that we can identify.

Due to the way glaciers melt, which depends on seasonal changes in temperature, there is an annual melting of ice. This leads to an annual increase in minor sediments falling from under the ice into the lake. If we then look into the lake, we see stratification (rhythmic layered sediments) there, which is also known by the Swedish name "varves" (varve), which means "annual accumulations". So we can actually see annual layering in glacial lakes. We can even count these varves and find out how long this lake has existed. In general, with the help of this material, we can get a lot of information.

In Antarctica, we can see huge ice shelves that come off the land into the sea. And of course, ice is buoyant, so it floats on water. As it swims, it carries pebbles and minor sediments with it. Due to the thermal action of the water, the ice melts and sheds this material. This leads to the formation of the process of the so-called rafting of rocks that go into the ocean. When we see fossil deposits from this period, we can find out where the glacier was, how far it extended, and so on.

Causes of glaciation

Researchers believe that ice ages occur because the Earth's climate depends on the uneven heating of its surface by the Sun. So, for example, the equatorial regions, where the Sun is almost vertically overhead, are the warmest zones, and the polar regions, where it is at a large angle to the surface, are the coldest. This means that the difference in heating of different parts of the Earth's surface controls the ocean-atmospheric machine, which is constantly trying to transfer heat from the equatorial regions to the poles.

If the Earth were an ordinary sphere, this transfer would be very efficient, and the contrast between the equator and the poles would be very small. So it was in the past. But since there are now continents, they get in the way of this circulation, and the structure of its flows becomes very complex. Simple currents are restrained and altered, in large part by mountains, leading to the circulation patterns we see today that drive the trade winds and ocean currents. For example, one of the theories about why the ice age began 2.5 million years ago links this phenomenon with the emergence of the Himalayan mountains. The Himalayas are still growing very fast and it turns out that the existence of these mountains in a very warm part of the Earth governs things like the monsoon system. The beginning of the Quaternary Ice Age is also associated with the closing of the Isthmus of Panama, which connects the north and south of America, which prevented the transfer of heat from the equatorial Pacific to the Atlantic.

If the position of the continents relative to each other and relative to the equator allowed the circulation to work efficiently, then it would be warm at the poles, and relatively warm conditions would persist throughout the earth's surface. The amount of heat received by the Earth would be constant and vary only slightly. But since our continents create serious barriers to circulation between north and south, we have pronounced climatic zones. This means that the poles are relatively cold while the equatorial regions are warm. When things are happening as they are now, the Earth can change with variations in the amount of solar heat it receives.

These variations are almost completely constant. The reason for this is that over time the earth's axis changes, as does the earth's orbit. Given this complex climatic zoning, orbital change could contribute to long-term changes in climate, resulting in climate wobble. Because of this, we have not continuous icing, but periods of icing, interrupted by warm periods. This happens under the influence of orbital changes. The latest orbital changes are seen as three separate phenomena: one 20,000 years long, the second 40,000 years long, and the third 100,000 years long.

This led to deviations in the pattern of cyclic climate change during the Ice Age. The icing most likely occurred during this cyclic period of 100,000 years. The last interglacial epoch, which was as warm as the current one, lasted about 125,000 years, and then came a long ice epoch, which took about 100,000 years. We are now living in another interglacial era. This period will not last forever, so another ice age awaits us in the future.

Why do ice ages end?

Orbital changes change the climate, and it turns out that ice ages are characterized by alternating cold periods, which can last up to 100,000 years, and warm periods. We call them the glacial (glacial) and interglacial (interglacial) epochs. An interglacial era is usually characterized by conditions similar to what we see today: high sea levels, limited areas of icing, and so on. Naturally, even now there are glaciations in Antarctica, Greenland and other similar places. But in general, the climatic conditions are relatively warm. This is the essence of interglacial: high sea level, warm temperature conditions and, in general, a fairly even climate.

But during the ice age, the average annual temperature changes significantly, the vegetative belts are forced to shift north or south, depending on the hemisphere. Regions like Moscow or Cambridge become uninhabited, at least in winter. Although they may be habitable in summer due to the strong contrast between seasons. But what is actually happening is that the cold zones are expanding substantially, the average annual temperature is dropping, and the overall climate is getting very cold. While the largest glacial events are relatively limited in time (perhaps around 10,000 years), the entire long cold period can last 100,000 years or more. This is what the glacial-interglacial cycle looks like.

Due to the length of each period, it is difficult to say when we will exit the current era. This is due to plate tectonics, the location of the continents on the surface of the Earth. Currently, the North Pole and South Pole are isolated, with Antarctica at the South Pole and the Arctic Ocean to the north. Because of this, there is a problem with heat circulation. As long as the location of the continents does not change, this ice age will continue. In line with long-term tectonic changes, it can be assumed that it will take another 50 million years in the future until significant changes occur that allow the Earth to emerge from the ice age.

Geological implications

This frees up huge sections of the continental shelf that are flooded today. This will mean, for example, that one day it will be possible to walk from Britain to France, from New Guinea to Southeast Asia. One of the most critical places is the Bering Strait, which links Alaska with Eastern Siberia. It is quite small, about 40 meters, so if the sea level drops to a hundred meters, then this area will become land. This is also important because plants and animals will be able to migrate through these places and get into regions where they cannot go today. Thus, the colonization of North America depends on the so-called Beringia.

Animals and the Ice Age

It is important to remember that we ourselves are the "products" of the ice age: we evolved during it, so we can survive it. However, it is not a matter of individual individuals - it is a matter of the entire population. The problem today is that there are too many of us and our activities have significantly changed the natural conditions. Under natural conditions, many of the animals and plants that we see today have a long history and survive the ice age well, although there are some that evolved slightly. They migrate and adapt. There are zones in which animals and plants survived the Ice Age. These so-called refugiums were located further north or south from their present distribution.

But as a result of human activity, some species died or became extinct. This has happened on every continent, with the possible exception of Africa. A huge number of large vertebrates, namely mammals, as well as marsupials in Australia, were exterminated by man. This was caused either directly by our activities, such as hunting, or indirectly by the destruction of their habitat. Animals living in northern latitudes today lived in the Mediterranean in the past. We have destroyed this region so much that it will most likely be very difficult for these animals and plants to colonize it again.

Consequences of global warming

Under normal conditions, by geological standards, we would soon enough return to the Ice Age. But because of global warming, which is a consequence of human activity, we are postponing it. We will not be able to completely prevent it, since the causes that caused it in the past still exist today. Human activity, an unforeseen element of nature, affects atmospheric warming, which may have already caused a delay in the next glacial.

Today, climate change is a very relevant and exciting issue. If the Greenland Ice Sheet melts, sea levels will rise by six meters. In the past, during the previous interglacial epoch, which was about 125,000 years ago, the Greenland Ice Sheet melted profusely, and sea levels were 4–6 meters higher than today. It's certainly not the end of the world, but it's not time complexity either. After all, the Earth has recovered from catastrophes before, it will be able to survive this one.

The long-term outlook for the planet is not bad, but for humans, that's a different matter. The more research we do, the better we understand how the Earth is changing and where it leads, the better we understand the planet we live on. This is important because people are finally starting to think about changing sea levels, global warming and the impact of all these things on agriculture and the population. Much of this has to do with the study of ice ages. Through these studies, we will learn the mechanisms of glaciations, and we can use this knowledge proactively, trying to mitigate some of the changes that we ourselves are causing. This is one of the main results and one of the goals of research on ice ages.
Of course, the main consequence of the Ice Age is huge ice sheets. Where does water come from? Of course, from the oceans. What happens during ice ages? Glaciers form as a result of precipitation on land. Due to the fact that the water does not return to the ocean, the sea level falls. During the most severe glaciations, sea levels can drop by more than a hundred meters.

Climatic changes were most clearly expressed in periodically advancing ice ages, which had a significant impact on the transformation of the land surface under the body of the glacier, water bodies and biological objects that are in the zone of influence of the glacier.

According to the latest scientific data, the duration of glacial eras on Earth is at least a third of the entire time of its evolution over the past 2.5 billion years. And if we take into account the long initial phases of the origin of glaciation and its gradual degradation, then the epochs of glaciation will take almost as much time as warm, ice-free conditions. The last of the ice ages began almost a million years ago, in the Quaternary, and was marked by an extensive spread of glaciers - the Great Glaciation of the Earth. The northern part of the North American continent, a significant part of Europe, and possibly Siberia as well, were under thick ice sheets. In the Southern Hemisphere, under the ice, as now, was the entire Antarctic continent.

The main causes of glaciation are:

space;

astronomical;

geographical.

Cosmic Cause Groups:

change in the amount of heat on the Earth due to the passage of the solar system 1 time/186 million years through the cold zones of the Galaxy;

change in the amount of heat received by the Earth due to a decrease in solar activity.

Astronomical groups of causes:

change in the position of the poles;

the inclination of the earth's axis to the plane of the ecliptic;

change in the eccentricity of the Earth's orbit.

Geological and geographical groups of causes:

climate change and the amount of carbon dioxide in the atmosphere (increase in carbon dioxide - warming; decrease - cooling);

change in the direction of ocean and air currents;

intensive process of mountain building.

Conditions for the manifestation of glaciation on Earth include:

snowfall in the form of precipitation at low temperatures with its accumulation as a material for building up a glacier;

negative temperatures in areas where there are no glaciations;

periods of intense volcanism due to the huge amount of ash emitted by volcanoes, which leads to a sharp decrease in the flow of heat (sun rays) to the earth's surface and causes global temperature decreases by 1.5-2ºС.

The oldest glaciation is the Proterozoic (2300-2000 million years ago) in South Africa, North America, and Western Australia. In Canada, 12 km of sedimentary rocks were deposited, in which three thick strata of glacial origin are distinguished.

Established ancient glaciations (Fig. 23):

on the border of the Cambrian-Proterozoic (about 600 million years ago);

late Ordovician (about 400 million years ago);

Permian and Carboniferous periods (about 300 million years ago).

The duration of ice ages is tens to hundreds of thousands of years.

Rice. 23. Geochronological scale of geological epochs and ancient glaciations

During the period of maximum distribution of the Quaternary glaciation, glaciers covered over 40 million km 2 - about a quarter of the entire surface of the continents. The largest in the Northern Hemisphere was the North American Ice Sheet, reaching a thickness of 3.5 km. Under the ice sheet up to 2.5 km thick was the whole of northern Europe. Having reached the greatest development 250 thousand years ago, the Quaternary glaciers of the Northern Hemisphere began to gradually shrink.

Before the Neogene period, the entire Earth had an even warm climate - in the region of the islands of Svalbard and Franz Josef Land (according to paleobotanical finds of subtropical plants) at that time there were subtropics.

Reasons for the cooling of the climate:

the formation of mountain ranges (Cordillera, Andes), which isolated the Arctic region from warm currents and winds (uplift of mountains by 1 km - cooling by 6ºС);

creation of a cold microclimate in the Arctic region;

cessation of heat supply to the Arctic region from warm equatorial regions.

By the end of the Neogene period, North and South America joined, which created obstacles for the free flow of ocean waters, as a result of which:

equatorial waters turned the current to the north;

the warm waters of the Gulf Stream, cooling sharply in northern waters, created a steam effect;

precipitation of a large amount of precipitation in the form of rain and snow has increased sharply;

a decrease in temperature by 5-6ºС led to the glaciation of vast territories (North America, Europe);

a new period of glaciation began, lasting about 300 thousand years (the frequency of glacier-interglacial periods from the end of the Neogene to the Anthropogen (4 glaciations) is 100 thousand years).

Glaciation was not continuous throughout the Quaternary period. There is geological, paleobotanical and other evidence that during this time the glaciers completely disappeared at least three times, giving way to interglacial epochs when the climate was warmer than the present. However, these warm epochs were replaced by cooling periods, and glaciers spread again. At present, the Earth is at the end of the fourth era of the Quaternary glaciation, and, according to geological forecasts, our descendants in a few hundred-thousand years will again find themselves in the conditions of an ice age, and not warming.

The Quaternary glaciation of Antarctica developed along a different path. It arose many millions of years before the time when glaciers appeared in North America and Europe. In addition to climatic conditions, this was facilitated by the high mainland that existed here for a long time. Unlike the ancient ice sheets of the Northern Hemisphere, which disappeared and reappeared, the Antarctic ice sheet has changed little in its size. The maximum glaciation of Antarctica was only one and a half times greater than the current one in terms of volume and not much more in area.

The culmination of the last ice age on Earth was 21-17 thousand years ago (Fig. 24), when the volume of ice increased to approximately 100 million km3. In Antarctica, glaciation at that time captured the entire continental shelf. The volume of ice in the ice sheet, apparently, reached 40 million km 3, that is, it was about 40% more than its present volume. The boundary of the pack ice shifted to the north by approximately 10°. In the Northern Hemisphere 20 thousand years ago, a giant Panarctic ancient ice sheet was formed, uniting the Eurasian, Greenland, Laurentian and a number of smaller shields, as well as extensive floating ice shelves. The total volume of the shield exceeded 50 million km3, and the level of the World Ocean dropped by at least 125m.

The degradation of the Panarctic cover began 17 thousand years ago with the destruction of the ice shelves that were part of it. After that, the "marine" parts of the Eurasian and North American ice sheets, which lost their stability, began to disintegrate catastrophically. The disintegration of the glaciation occurred in just a few thousand years (Fig. 25).

Huge masses of water flowed from the edge of the ice sheets at that time, giant dammed lakes arose, and their breakthroughs were many times larger than modern ones. In nature, spontaneous processes dominated, immeasurably more active than now. This led to a significant renewal of the natural environment, a partial change in the animal and plant world, and the beginning of human dominance on Earth.

The last retreat of the glaciers, which began over 14 thousand years ago, remains in the memory of people. Apparently, it is the process of melting glaciers and raising the water level in the ocean with extensive flooding of territories that is described in the Bible as a global flood.

12 thousand years ago the Holocene began - the modern geological epoch. The air temperature in temperate latitudes increased by 6° compared to the cold Late Pleistocene. Glaciation took on modern dimensions.

In the historical epoch - approximately for 3 thousand years - the advance of glaciers occurred in separate centuries with low air temperature and increased humidity and were called small ice ages. The same conditions developed in the last centuries of the last era and in the middle of the last millennium. About 2.5 thousand years ago, a significant cooling of the climate began. The Arctic islands were covered with glaciers, in the countries of the Mediterranean and the Black Sea on the verge of a new era, the climate was colder and wetter than now. In the Alps in the 1st millennium BC. e. glaciers moved to lower levels, cluttered mountain passes with ice and destroyed some high-lying villages. This epoch is marked by a major advance of the Caucasian glaciers.

The climate at the turn of the 1st and 2nd millennium AD was quite different. Warmer conditions and the lack of ice in the northern seas allowed the navigators of Northern Europe to penetrate far north. From 870, the colonization of Iceland began, where at that time there were fewer glaciers than now.

In the 10th century, the Normans, led by Eirik the Red, discovered the southern tip of a huge island, the shores of which were overgrown with thick grass and tall shrubs, they founded the first European colony here, and this land was called Greenland, or “green land” (which is by no means now say about the harsh lands of modern Greenland).

By the end of the 1st millennium, mountain glaciers in the Alps, the Caucasus, Scandinavia, and Iceland also retreated strongly.

The climate began to seriously change again in the 14th century. Glaciers began to advance in Greenland, the summer thawing of soils became more and more short-lived, and by the end of the century, permafrost was firmly established here. The ice cover of the northern seas increased, and attempts made in subsequent centuries to reach Greenland by the usual route ended in failure.

From the end of the 15th century, the advance of glaciers began in many mountainous countries and polar regions. After the relatively warm 16th century, harsh centuries came, which were called the Little Ice Age. In the south of Europe, severe and long winters often repeated, in 1621 and 1669 the Bosphorus froze, and in 1709 the Adriatic Sea froze along the shores.

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About the second half of the 19th century, the Little Ice Age ended and a relatively warm era began, which continues to this day.

Rice. 24. The boundaries of the last glaciation

Rice. 25. Scheme of the formation and melting of the glacier (along the profile of the Arctic Ocean - Kola Peninsula - Russian Platform)

Consider such a phenomenon as periodic ice ages on Earth. In modern geology, it is generally accepted that our Earth periodically experiences Ice Ages in its history. During these epochs, the Earth's climate becomes sharply colder, and the Arctic and Antarctic polar caps monstrously increase in size. Not so many thousands of years ago, as we were taught, vast expanses of Europe and North America were covered with ice. Eternal ice lay not only on the slopes of high mountains, but also covered the continents with a thick layer even in temperate latitudes. Where the Hudson, the Elbe and the Upper Dnieper flow today, there was a frozen desert. All this was like an endless glacier, and now covers the island of Greenland. There are indications that the retreat of the glaciers has been halted by new ice masses and that their boundaries have varied over time. Geologists can determine the boundaries of glaciers. Traces of five or six successive movements of ice during the ice age, or five or six ice ages, have been found. Some force pushed the ice layer to temperate latitudes. Until now, neither the cause of the appearance of glaciers, nor the cause of the retreat of the ice desert is known; the timing of this retreat is also a matter of dispute. Many ideas and conjectures have been put forward to explain how the ice age began and why it ended. Some have thought that the Sun radiated more or less heat in different epochs, which explains the periods of heat or cold on the Earth; but we do not have sufficient evidence that the Sun is such a "changing star" to accept this hypothesis. The reason for the Ice Age is seen by some scientists as a decrease in the initially high temperature of the planet. Warm periods between glacial periods have been associated with heat released from the supposed decomposition of organisms in layers close to the earth's surface. The increase and decrease in the activity of hot springs were also taken into account.

Many ideas and conjectures have been put forward to explain how the ice age began and why it ended. Some have thought that the Sun radiated more or less heat in different epochs, which explains the periods of heat or cold on the Earth; but we do not have sufficient evidence that the Sun is such a "changing star" to accept this hypothesis.

Others have argued that there are colder and warmer zones in outer space. As our solar system passes through regions of cold, the ice descends in latitude closer to the tropics. But no physical factors have been found to create similar cold and warm zones in space.

Some have wondered whether precession, or the slow reversal of the earth's axis, could cause periodic fluctuations in climate. But it has been proven that this change alone cannot be so significant as to cause an ice age.

Also, scientists were looking for an answer in periodic variations in the eccentricity of the ecliptic (earth's orbit) with the phenomenon of glaciation at maximum eccentricity. Some researchers believed that winter in aphelion, the most distant part of the ecliptic, could lead to glaciation. And others believed that summer at aphelion could cause such an effect.

The reason for the Ice Age is seen by some scientists as a decrease in the initially high temperature of the planet. Warm periods between glacial periods have been associated with heat released from the supposed decomposition of organisms in layers close to the earth's surface. The increase and decrease in the activity of hot springs were also taken into account.

There is a point of view that the dust of volcanic origin filled the earth's atmosphere and caused insulation, or, on the other hand, the increasing amount of carbon monoxide in the atmosphere prevented the reflection of heat rays from the surface of the planet. An increase in the amount of carbon monoxide in the atmosphere can cause a drop in temperature (Arrhenius), but calculations have shown that this could not be the true cause of the ice age (Angstrom).

All other theories are also hypothetical. The phenomenon that underlies all these changes has never been precisely defined, and those that were named could not produce a similar effect.

Not only are the causes of the appearance and subsequent disappearance of ice sheets unknown, but the geographic relief of the area covered with ice remains a problem. Why did the ice cover in the southern hemisphere move from the tropical regions of Africa towards the South Pole, and not in the opposite direction? And why in the northern hemisphere did ice move into India from the equator towards the Himalayas and higher latitudes? Why did glaciers cover most of North America and Europe, while North Asia was free of them?

In America, the ice plain extended to a latitude of 40° and even went beyond this line, in Europe it reached a latitude of 50°, and North-Eastern Siberia, above the Arctic Circle, even at a latitude of 75° was not covered by this eternal ice. All hypotheses regarding the increasing and decreasing isolation associated with the change of the sun or temperature fluctuations in outer space, and other similar hypotheses, cannot but encounter this problem.

Glaciers formed in permafrost regions. For this reason, they remained on the slopes of high mountains. The north of Siberia is the coldest place on Earth. Why did the ice age not touch this area, although it covered the Mississippi basin and all of Africa south of the equator? No satisfactory answer to this question has been offered.

During the Last Ice Age, at the peak of the glaciation, which was observed 18,000 years ago (on the eve of the Great Flood), the borders of the glacier in Eurasia passed along approximately 50 ° north latitude (latitude of Voronezh), and the border of the glacier in North America even along 40 ° (latitude New York). At the South Pole, glaciation took over southern South America, and possibly also New Zealand and southern Australia.

The theory of ice ages was first presented in the work of the father of glaciology, Jean Louis Agassiz, "Etudes sur les glaciers" (1840). Over the past century and a half, glaciology has been replenished with a huge amount of new scientific data, and the maximum boundaries of the Quaternary glaciation were determined with a high degree of accuracy.
However, for the entire time of the existence of glaciology, it failed to establish the most important thing - to determine the causes of the onset and retreat of ice ages. None of the hypotheses put forward during this time has received the approval of the scientific community. And today, for example, in the Russian-language Wikipedia article “Ice Age” you will not find the section “Causes of Ice Ages”. And not because this section was forgotten to be placed here, but because no one knows these reasons. What are the real reasons?
Paradoxically, in fact, there have never been any ice ages in the history of the Earth. The temperature and climate regime of the Earth is set mainly by four factors: the intensity of the Sun's glow; orbital distance of the Earth from the Sun; the angle of inclination of the axial rotation of the Earth to the plane of the ecliptic; as well as the composition and density of the earth's atmosphere.

These factors, as scientific data show, remained stable throughout at least the last Quaternary period. Consequently, there were no reasons for a sharp change in the Earth's climate in the direction of cooling.

What is the reason for the monstrous growth of glaciers during the Last Ice Age? The answer is simple: in the periodic change in the location of the earth's poles. And here it should immediately be added: the monstrous growth of the Glacier during the Last Ice Age is an apparent phenomenon. In fact, the total area and volume of the Arctic and Antarctic glaciers have always remained approximately constant - while the North and South Poles changed their position with an interval of 3,600 years, which predetermined the wandering of polar glaciers (caps) on the Earth's surface. Exactly as much glacier formed around the new poles as it melted in those places where the poles left. In other words, the Ice Age is a very relative concept. When the North Pole was in North America, there was an ice age for its inhabitants. When the North Pole moved to Scandinavia, the Ice Age began in Europe, and when the North Pole “left” into the East Siberian Sea, the Ice Age “came” to Asia. An ice age is currently in full swing for the supposed inhabitants of Antarctica and the former inhabitants of Greenland, which is constantly melting in the southern part, as the previous pole shift was not strong and moved Greenland a little closer to the equator.

Thus, there have never been ice ages in the history of the Earth, and at the same time they have always been. Such is the paradox.

The total area and volume of glaciation on the planet Earth has always been, is and will be generally constant as long as the four factors that determine the climate regime of the Earth are constant.
During the pole shift, there are several ice sheets on the Earth at the same time, usually two melting and two newly formed, depending on the angle of crustal displacement.

Pole shifts on Earth occur at intervals of 3,600-3,700 years, corresponding to the orbital period of Planet X around the Sun. These pole shifts lead to a redistribution of heat and cold zones on Earth, which is reflected in modern academic science in the form of continuously replacing each other stadials (cooling periods) and interstadials (warming periods). The average duration of both stadials and interstadials is determined in modern science at 3700 years, which correlates well with the orbital period of Planet X around the Sun - 3600 years.

From academic literature:

It must be said that in the last 80,000 years the following periods were observed in Europe (years BC):
Stadial (cooling) 72500-68000
Interstadial (warming) 68000-66500
Stadial 66500-64000
Interstadial 64000-60500
Stadial 60500-48500
Interstadial 48500-40000
Stadial 40000-38000
Interstadial 38000-34000
Stadial 34000-32500
Interstadial 32500-24000
Stadial 24000-23000
Interstadial 23000-21500
Stadial 21500-17500
Interstadial 17500-16000
Stadial 16000-13000
Interstadial 13000-12500
Stadial 12500-10000

Thus, in the course of 62 thousand years, 9 stadials and 8 interstadials happened in Europe. The average duration of a stadial is 3700 years, and an interstadial is also 3700 years. The largest stadial lasted 12,000 years, and the interstadial lasted 8,500 years.

In the post-Flood history of the Earth, 5 pole shifts occurred and, accordingly, 5 polar ice sheets successively replaced each other in the Northern Hemisphere: the Laurentian ice sheet (the last antediluvian), the Scandinavian Barents-Kara ice sheet, the East Siberian ice sheet, the Greenland ice sheet and the modern Arctic ice sheet.

The modern Greenland Ice Sheet deserves special attention as the third major ice sheet coexisting simultaneously with the Arctic Ice Sheet and the Antarctic Ice Sheet. The presence of a third large ice sheet does not at all contradict the above theses, since it is a well-preserved remnant of the previous North Polar Ice Sheet, where the North Pole was located during 5200-1600 years. BC. Connected with this fact is the answer to the riddle why the extreme north of Greenland today is not affected by glaciation - the North Pole was in the south of Greenland.

Accordingly, the location of the polar ice sheets in the southern hemisphere changed:

• 16,000 BCuh. (18,000 years ago) Recently, there has been a strong consensus in academic science regarding the fact that this year was both the peak of the maximum glaciation of the Earth and the beginning of the rapid melting of the Glacier. A clear explanation of neither one nor the other fact in modern science does not exist. What was this year famous for? 16,000 BC e. - this is the year of the 5th passage through the solar system, counting from the present moment ago (3600 x 5 = 18,000 years ago). This year, the North Pole was located on the territory of modern Canada in the Hudson Bay region. The South Pole was located in the ocean to the east of Antarctica, which suggested the glaciation of southern Australia and New Zealand. Bala's Eurasia is completely free of glaciers. “In the 6th year of K'an, the 11th day of Muluk, in the month of Sak, a terrible earthquake began and continued without interruption until 13 Kuen. The Land of the Clay Hills, the Land of Mu, was sacrificed. Having experienced two strong vibrations, she suddenly disappeared during the night;the soil was constantly shaking under the influence of underground forces, which raised and lowered it in many places, so that it settled; countries were separated from one another, then scattered. Unable to resist these terrible shudders, they failed, dragging the inhabitants with them. This happened 8050 years before this book was written.”("Code Troano" translated by Auguste Le Plongeon). The unprecedented magnitude of the catastrophe caused by the passage of Planet X has resulted in a very strong pole shift. The North Pole moves from Canada to Scandinavia, the South Pole to the ocean west of Antarctica. At the same time that the Laurentian Ice Sheet begins to melt rapidly, which coincides with the data of academic science about the end of the peak of glaciation and the beginning of the melting of the Glacier, the Scandinavian Ice Sheet is formed. At the same time, the Australian and South Zealand ice sheets melt and the Patagonian Ice Sheet forms in South America. These four ice sheets coexist for only a relatively short time, which is necessary for the two previous ice sheets to completely melt and two new ones to form.

• 12,400 BC The North Pole is moving from Scandinavia to the Barents Sea. In this regard, the Barents-Kara ice sheet is formed, but the Scandinavian ice sheet is melting only slightly, as the North Pole moves a relatively small distance. In academic science, this fact has found the following reflection: “The first signs of an interglacial period (which is still ongoing) appeared as early as 12,000 BC.”
• 8 800 BC The North Pole moves from the Barents Sea to the East Siberian Sea, in connection with which the Scandinavian and Barents-Kara ice sheets are melting, and the East Siberian ice sheet is formed. This pole shift killed off most of the mammoths. Quote from an academic study: “About 8000 BC. e. a sharp warming led to the retreat of the glacier from its last line - a wide strip of moraines stretching from central Sweden through the Baltic Sea basin to southeast Finland. Approximately at this time, the disintegration of a single and homogeneous periglacial zone occurs. In the temperate zone of Eurasia, forest vegetation predominates. To the south of it, forest-steppe and steppe zones are formed.
• 5 200 BC The North Pole is moving from the East Siberian Sea to Greenland, causing the East Siberian Ice Sheet to melt and the Greenland Ice Sheet to form. Hyperborea is freed from ice, and a wonderful temperate climate is established in the Trans-Urals and Siberia. Ariavarta, the country of the Aryans, flourishes here.
• 1600 BC Past shift. The North Pole moves from Greenland to the Arctic Ocean to its current position. The Arctic Ice Sheet emerges, but the Greenland Ice Sheet remains at the same time. The last mammoths living in Siberia freeze very quickly with undigested green grass in their stomachs. Hyperborea is completely hidden under the modern Arctic ice sheet. Most of the Trans-Urals and Siberia become unsuitable for human existence, which is why the Aryans undertake their famous Exodus to India and Europe, and the Jews also make their exodus from Egypt.

“In the permafrost of Alaska ... one can find ... evidence of atmospheric disturbances of incomparable power. Mammoths and bison were torn apart and twisted as if some cosmic arms of the gods were acting in rage. In one place ... they found the front leg and shoulder of a mammoth; the blackened bones still held the remnants of soft tissues adjacent to the spine along with tendons and ligaments, and the chitinous sheath of the tusks was not damaged. There were no traces of dismemberment of carcasses with a knife or other tool (as would be the case if hunters were involved in the dismemberment). The animals were simply torn apart and scattered around the area like woven straw, although some of them weighed several tons. Mixed with clusters of bones are trees, also torn, twisted and tangled; all this is covered with fine-grained quicksand, subsequently tightly frozen” (G. Hancock, “Traces of the Gods”).

Frozen mammoths

Northeastern Siberia, which was not covered by glaciers, holds another mystery. Its climate has changed dramatically since the end of the ice age, and the average annual temperature has fallen many degrees below its previous level. The animals that once lived in the area could no longer live here, and the plants that used to grow there were no longer able to grow here. Such a change must have happened quite suddenly. The reason for this event is not explained. During this catastrophic climate change and under mysterious circumstances, all Siberian mammoths perished. And it happened only 13 thousand years ago, when the human race was already widespread throughout the planet. For comparison: Late Paleolithic rock paintings found in the caves of Southern France (Lascaux, Chauvet, Rouffignac, etc.) were made 17-13 thousand years ago.

Such an animal lived on earth - a mammoth. They reached a height of 5.5 meters and a body weight of 4-12 tons. Most mammoths died out about 11-12 thousand years ago during the last cooling of the Vistula Ice Age. This is what science tells us, and draws a picture like the one above. True, not very concerned about the question - what did these woolly elephants weighing 4-5 tons eat on such a landscape. “Of course, since it’s written in books like that”- Allen nod. Reading very selectively, and considering the given picture. About the fact that during the life of mammoths on the territory of the current tundra, birch grew (which is written in the same book, and other deciduous forests - that is, a completely different climate) - they somehow do not notice. The diet of mammoths was mainly vegetable, and adult males daily ate about 180 kg of food.

While the number of woolly mammoths was truly impressive. For example, between 1750 and 1917, the mammoth ivory trade flourished over a wide area, and 96,000 mammoth tusks were discovered. According to various estimates, about 5 million mammoths lived in a small part of northern Siberia.

Before their extinction, woolly mammoths inhabited vast parts of our planet. Their remains have been found throughout Northern Europe, Northern Asia and North America.

Woolly mammoths were not a new species. They have inhabited our planet for six million years.

A biased interpretation of the hairy and fatty constitution of the mammoth, as well as a belief in unchanging climatic conditions, led scientists to the conclusion that the woolly mammoth was an inhabitant of the cold regions of our planet. But fur-bearing animals do not have to live in cold climates. Take for example desert animals like camels, kangaroos and phoenixes. They are furry but live in hot or temperate climates. Actually most fur-bearing animals would not be able to survive in arctic conditions.

For successful cold adaptation, it is not enough just to have a coat. For adequate thermal insulation from the cold, the coat should be in an elevated state. Unlike Antarctic fur seals, mammoths lacked raised fur.

Another factor of sufficient protection against cold and humidity is the presence of sebaceous glands, which secrete oils on the skin and fur, and thus protect against moisture.

Mammoths did not have sebaceous glands, and their dry hair allowed the snow to touch the skin, melt, and significantly increase heat loss (the thermal conductivity of water is about 12 times higher than that of snow).

As seen in the photo above, mammoth fur was not dense. In comparison, the fur of a yak (a cold-adapted Himalayan mammal) is about 10 times thicker.

In addition, mammoths had hair that hung down to their toes. But every arctic animal has hair on its toes or paws, not hair. Hair would collect snow on the ankle joint and interfere with walking.

The above clearly shows that fur and body fat are not proof of cold adaptation. The fat layer only indicates the abundance of food. A fat, overfed dog would not have been able to withstand an arctic blizzard and a temperature of -60°C. But arctic rabbits or caribou can, despite their relatively low fat content relative to total body weight.

As a rule, the remains of mammoths are found with the remains of other animals, such as: tigers, antelopes, camels, horses, reindeer, giant beavers, giant bulls, sheep, musk oxen, donkeys, badgers, alpine goats, woolly rhinos, foxes, giant bison, lynx, leopard, wolverine, hares, lions, elks, giant wolves, gophers, cave hyenas, bears, and many bird species. Most of these animals would not be able to survive in the arctic climate. This is additional evidence that woolly mammoths were not polar animals.

The French prehistoric expert, Henry Neville, made the most detailed study of mammoth skin and hair. At the end of his careful analysis, he wrote the following:

"It is not possible for me to find in the anatomical study of their skin and [hair] any argument in favor of adaptation to cold."

— G. Neville, On the Extinction of the Mammoth, Smithsonian Institution Annual Report, 1919, p. 332.

Finally, the diet of mammoths contradicts the diet of animals living in polar climates. How could a woolly mammoth maintain its vegetarian diet in an arctic region, and eat hundreds of pounds of greens every day, when in such a climate most of the year there is none at all? How could woolly mammoths find liters of water for daily consumption?

To make matters worse, woolly mammoths lived during the Ice Age, when temperatures were cooler than they are today. Mammoths would not have been able to survive in the harsh climate of northern Siberia today, let alone 13,000 years ago, if the then climate had been much harsher.

The above facts indicate that the woolly mammoth was not a polar animal, but lived in a temperate climate. Consequently, at the beginning of the Younger Dryas, 13 thousand years ago, Siberia was not an arctic region, but a temperate one.

"A long time ago, however, they died"- the reindeer breeder agrees, cutting off a piece of meat from the found carcass in order to feed the dogs.

"Hard"- says a more vital geologist, chewing a piece of barbecue taken from a makeshift skewer.

Frozen mammoth meat initially looked absolutely fresh, dark red in color, with appetizing streaks of fat, and the expedition even wanted to try to eat it. But as it thawed, the meat became flabby, dark gray in color, with an unbearable smell of decomposition. However, the dogs happily ate the millennial ice cream delicacy, from time to time arranging internecine fights over the most tidbits.

One more moment. Mammoths are rightly called fossils. Because in our time they are simply dug. For the purpose of obtaining tusks for crafts.

It is estimated that for two and a half centuries in the north-east of Siberia, tusks belonging to at least forty-six thousand (!) Mammoths were collected (the average weight of a pair of tusks is close to eight pounds - about one hundred and thirty kilograms).

Mammoth tusks are DIGGING. That is, they are mined from underground. Somehow, the question does not even arise - why have we forgotten how to see the obvious? Did mammoths dig holes for themselves, lay down in them for winter hibernation, and then they fell asleep? But how did they end up underground? At a depth of 10 meters or more? Why are mammoth tusks dug from river banks? And, massively. So massively that a bill was submitted to the State Duma equating mammoths with minerals, as well as introducing a tax on their extraction.

But for some reason they are digging massively only here in the north. And now the question arises - what happened that whole mammoth cemeteries were formed here?

What caused such an almost instantaneous mass pestilence?

Over the past two centuries, numerous theories have been proposed that attempt to explain the sudden extinction of woolly mammoths. They got stuck in frozen rivers, were over-hunted, and fell into ice crevices at the height of the global glaciation. But none of the theories adequately explains this mass extinction.

Let's try to think for ourselves.

Then the following logical chain should line up:

1. There were a lot of mammoths.
2. Since there were a lot of them, they should have had a good food base - not the tundra, where they are now found.
3. If it was not the tundra, the climate in those places was somewhat different, much warmer.
4. A slightly different climate OUTSIDE the Arctic Circle could only be if it was not TRANSArctic at that time.
5. Mammoth tusks, and whole mammoths themselves, are found underground. They somehow got there, some event occurred that covered them with a layer of soil.
6. Taking it as an axiom that mammoths themselves did not dig holes, only water could bring this soil, first surging, and then descending.
7. The layer of this soil is thick - meters, and even tens of meters. And the amount of water that applied such a layer must have been very large.
8. Mammoth carcasses are found in a very well-preserved condition. Immediately after washing the corpses with sand, their freezing followed, which was very fast.

They almost instantly froze on giant glaciers, the thickness of which was many hundreds of meters, to which they were carried by a tidal wave caused by a change in the angle of the earth's axis. This gave rise to the unjustified assumption among scientists that the animals of the middle belt went deep into the North in search of food. All remains of mammoths were found in sands and clays deposited by mud flows.

Such powerful mudflows are possible only during extraordinary major disasters, because at that time dozens, and possibly hundreds and thousands of animal cemeteries were formed throughout the North, into which not only the inhabitants of the northern regions, but also animals from regions with a temperate climate were washed away . And this allows us to believe that these giant animal cemeteries were formed by a tidal wave of incredible power and size, which literally rolled over the continents and retreating back into the ocean, carried away thousands of herds of large and small animals with it. And the most powerful mudflow "tongue", containing giant accumulations of animals, reached the New Siberian Islands, which were literally covered with loess and countless bones of various animals.

A giant tidal wave washed away gigantic herds of animals from the face of the Earth. These huge herds of drowned animals, lingering in natural barriers, terrain folds and floodplains, formed countless animal cemeteries, in which animals of various climatic zones appeared to be mixed.

Scattered bones and molars of mammoths are often found in sediments and sedimentary rocks at the bottom of the oceans.

The most famous, but far from the largest cemetery of mammoths in Russia, is the Berelekh burial. Here is how N.K. describes the mammoth cemetery in Berelekh. Vereshchagin: “Yar is crowned with a melting edge of ice and mounds ... A kilometer later, an extensive scattering of huge gray bones appeared - long, flat, short. They protrude from the dark damp ground in the middle of the slope of the ravine. Sliding down to the water along a slightly turfed slope, the bones formed a spit-toe protecting the shore from erosion. There are thousands of them, the scattering stretches along the coast for about two hundred meters and goes into the water. The opposite, right bank is only eighty meters away, low, alluvial, behind it is an impenetrable willow growth ... everyone is silent, depressed by what they saw ".In the area of ​​the Berelekh cemetery there is a thick layer of clay-ash loess. Signs of an extremely large floodplain sediment are clearly traced. In this place, a huge mass of fragments of branches, roots, bone remains of animals has accumulated. The animal cemetery was washed away by the river, which, twelve millennia later, returned to its former course. Scientists who studied the Berelekh cemetery found among the remains of mammoths, a large number of bones of other animals, herbivores and predators, which under normal conditions are never found in huge clusters together: foxes, hares, deer, wolves, wolverines and other animals.

The theory of repeated catastrophes that destroy life on our planet and repeat the creation or restoration of life forms, proposed by Deluc and developed by Cuvier, did not convince the scientific world. Both Lamarck before Cuvier and Darwin after him believed that a progressive, slow, evolutionary process governs genetics and that there are no catastrophes that interrupt this process of infinitesimal changes. According to the theory of evolution, these minor changes are the result of adaptation to the conditions of life in the struggle of species for survival.

Darwin admitted that he was unable to explain the disappearance of the mammoth, an animal much better developed than the elephant, which survived. But in accordance with the theory of evolution, his followers believed that the gradual subsidence of the soil forced the mammoths to climb the hills, and they turned out to be swamps closed on all sides. However, if geological processes are slow, mammoths would not be trapped on isolated hills. Besides, this theory cannot be true, because the animals did not die of starvation. Undigested grass was found in their stomachs and between their teeth. This, by the way, also proves that they died suddenly. Further research showed that the branches and leaves found in their stomachs do not grow in the areas where the animals died, but further south, at a distance of more than a thousand miles. It seems that the climate has changed radically since the death of the mammoths. And since the bodies of the animals were found undecayed, but well preserved in ice blocks, a change in temperature must have followed immediately after their death.

Documentary

Risking their lives and being in great danger, scientists in Siberia are looking for a single frozen mammoth cell. With the help of which it will be possible to clone and thereby bring back to life a long-extinct animal species.

It remains to be added that after storms in the Arctic, mammoth tusks are carried to the shores of the Arctic islands. This proves that the part of the land where the mammoths lived and drowned was heavily flooded.

For some reason, modern scientists do not take into account the facts of the presence of a geotectonic catastrophe in the recent past of the Earth. It is in the recent past.
Although for them it is already an indisputable fact of the catastrophe from which the dinosaurs died. But they attribute this event to the times of 60-65 million years ago.
There are no versions that would combine the temporary facts of the death of dinosaurs and mammoths - at the same time. Mammoths lived in temperate latitudes, dinosaurs - in the southern regions, but died at the same time.
But no, no attention is paid to the geographic attachment of animals of different climatic zones, but there is still a temporary separation.
The facts of the sudden death of a huge number of mammoths in different parts of the world have already accumulated a lot. But here the scientists again stray from the obvious conclusions.
Not only did the representatives of science age all the mammoths by 40 thousand years, but they also invent versions of the natural processes in which these giants died.

American, French and Russian scientists have performed the first CT scans of Luba and Khroma, the youngest and best preserved mammoths.

Computed tomography (CT) slices were presented in the new issue of the Journal of Paleontology, and a summary of the results of the work can be found on the website of the University of Michigan.

Reindeer herders found Lyuba in 2007, on the banks of the Yuribey River on the Yamal Peninsula. Her corpse reached the scientists with almost no damage (only the tail was bitten off by dogs).

Chrome (this is a "boy") was discovered in 2008 on the banks of the river of the same name in Yakutia - crows and arctic foxes ate his trunk and part of his neck. Mammoths have well-preserved soft tissues (muscles, fat, internal organs, skin). Chroma was even found to have clotted blood in intact vessels and undigested milk in her stomach. The chroma was scanned in a French hospital. And at the University of Michigan, scientists took CT scans of animal teeth.

Thanks to this, it turned out that Lyuba died at the age of 30-35 days, and Khroma - 52-57 days (both mammoths were born in the spring).

Both mammoths died, choking on silt. CT scans showed a dense mass of fine-grained deposits obstructing the airways in the trunk.

The same deposits are present in Lyuba's throat and bronchi - but not inside the lungs: this suggests that Lyuba did not drown in water (as was previously believed), but suffocated, inhaling liquid mud. Chroma had a broken spine and also had dirt in his airways.

So, scientists once again confirmed our version of a global mudflow that covered the current north of Siberia and destroyed everything living there, covering a vast territory with “fine-grained sediments that clogged the respiratory tract.”

After all, such finds are observed over a vast territory and it is absurd to assume that all the mammoths found at the same time and massively began to fall into rivers and swamps.

Plus, mammoths have typical injuries for those caught in a stormy mudflow - fractures of bones and spine.

Scientists have found a very interesting detail - the death occurred either in late spring or summer. After birth in the spring, mammoths lived until death for 30-50 days. That is, the time of the change of poles was probably in the summer.

Or here's another example:

A team of Russian and American paleontologists is studying a bison that has lain in permafrost in northeastern Yakutia for about 9,300 years.

The bison, found on the shores of Lake Chukchala, is unique in that it is the first representative of this species of bovids, found at such a venerable age in complete safety - with all parts of the body and internal organs.

He was found in a recumbent position with his legs bent under his belly, his neck outstretched, and his head lying on the ground. Usually in this position, ungulates rest or sleep, but in it they die a natural death.

The age of the body, determined using radiocarbon analysis, is 9310 years, that is, the bison lived in the early Holocene. Scientists also determined that his age before his death was about four years. The bison managed to grow up to 170 cm at the withers, the span of the horns reached an impressive 71 cm, and the weight was about 500 kg.

Researchers have already scanned the animal's brain, but the cause of his death is still a mystery. No injuries were found on the corpse, as well as no pathologies of internal organs and dangerous bacteria.