Who created the bomb. Who invented the Atomic bomb - When was it invented? The principle of a thermonuclear bomb

The hydrogen or thermonuclear bomb became the cornerstone of the arms race between the USA and the USSR. The two superpowers argued for several years about who would become the first owner of a new type of destructive weapon.

Thermonuclear weapon project

At the beginning of the Cold War, the test of a hydrogen bomb was the most important argument for the leadership of the USSR in the fight against the United States. Moscow wanted to achieve nuclear parity with Washington and invested huge amounts of money in the arms race. However, work on creating a hydrogen bomb began not thanks to generous funding, but because of reports from secret agents in America. In 1945, the Kremlin learned that the United States was preparing to create a new weapon. It was a superbomb, the project of which was called Super.

The source of valuable information was Klaus Fuchs, an employee of the Los Alamos National Laboratory in the USA. He provided the Soviet Union with specific information regarding the secret American development of a superbomb. By 1950, the Super project was thrown into the trash, as it became clear to Western scientists that such a new weapon scheme could not be implemented. The director of this program was Edward Teller.

In 1946, Klaus Fuchs and John developed the ideas of the Super project and patented their own system. The principle of radioactive implosion was fundamentally new in it. In the USSR, this scheme began to be considered a little later - in 1948. In general, we can say that at the starting stage it was completely based on American information received by intelligence. But by continuing research based on these materials, Soviet scientists were noticeably ahead of their Western colleagues, which allowed the USSR to obtain first the first, and then the most powerful thermonuclear bomb.

On December 17, 1945, at a meeting of a special committee created under the Council of People's Commissars of the USSR, nuclear physicists Yakov Zeldovich, Isaac Pomeranchuk and Julius Hartion made a report “Use of nuclear energy of light elements.” This paper examined the possibility of using a deuterium bomb. This speech marked the beginning of the Soviet nuclear program.

In 1946 theoretical research began to be carried out at the Institute of Chemical Physics. The first results of this work were discussed at one of the meetings of the Scientific and Technical Council in the First Main Directorate. Two years later, Lavrentiy Beria instructed Kurchatov and Khariton to analyze materials about the von Neumann system that were delivered to Soviet Union thanks to secret agents in the West. Data from these documents gave additional impetus to the research that led to the birth of the RDS-6 project.

"Evie Mike" and "Castle Bravo"

On November 1, 1952, the Americans tested the world's first thermonuclear device. It was not yet a bomb, but already its most important component. The explosion occurred on Enivotek Atoll, in Pacific Ocean. and Stanislav Ulam (each of them actually the creator of the hydrogen bomb) had recently developed a two-stage design, which the Americans tested. The device could not be used as a weapon, as it was produced using deuterium. In addition, it was distinguished by its enormous weight and dimensions. Such a projectile simply could not be dropped from an airplane.

The first hydrogen bomb was tested by Soviet scientists. After the United States learned about the successful use of the RDS-6s, it became clear that it was necessary to close the gap with the Russians in the arms race as quickly as possible. The American test took place on March 1, 1954. The Bikini Atoll in the Marshall Islands was chosen as the test site. The Pacific archipelagos were not chosen by chance. There was almost no population here (and the few people who lived on the nearby islands were evicted on the eve of the experiment).

The Americans' most destructive hydrogen bomb explosion became known as Castle Bravo. The charge power turned out to be 2.5 times higher than expected. The explosion led to radiation contamination of a large area (many islands and the Pacific Ocean), which led to a scandal and a revision of the nuclear program.

Development of RDS-6s

The project of the first Soviet thermonuclear bomb was called RDS-6s. The plan was written by the outstanding physicist Andrei Sakharov. In 1950, the USSR Council of Ministers decided to concentrate work on the creation of new weapons in KB-11. According to this decision, a group of scientists led by Igor Tamm went to the closed Arzamas-16.

The Semipalatinsk test site was prepared especially for this grandiose project. Before the hydrogen bomb test began, numerous measuring, filming and recording instruments were installed there. In addition, on behalf of scientists, almost two thousand indicators appeared there. The area affected by the hydrogen bomb test included 190 structures.

The Semipalatinsk experiment was unique not only because of the new type of weapon. Unique intakes designed for chemical and radioactive samples were used. Only a powerful shock wave could open them. Recording and filming instruments were installed in specially prepared fortified structures on the surface and in underground bunkers.

Alarm Clock

Back in 1946, Edward Teller, who worked in the USA, developed a prototype of the RDS-6s. It's called Alarm Clock. The project for this device was originally proposed as an alternative to the Super. In April 1947, a series of experiments began at the Los Alamos laboratory designed to study the nature of thermonuclear principles.

Scientists expected the greatest energy release from Alarm Clock. In the fall, Teller decided to use lithium deuteride as fuel for the device. The researchers had not yet used this substance, but expected that it would improve efficiency. Interestingly, Teller already noted in his memos the dependence of the nuclear program on further development computers. This technique was necessary for scientists to make more accurate and complex calculations.

Alarm Clock and RDS-6s had much in common, but they also differed in many ways. The American version was not as practical as the Soviet one due to its size. It inherited its large size from the Super project. In the end, the Americans had to abandon this development. The last studies took place in 1954, after which it became clear that the project was unprofitable.

Explosion of the first thermonuclear bomb

First in human history The hydrogen bomb test took place on August 12, 1953. In the morning, a bright flash appeared on the horizon, which was blinding even through protective glasses. The RDS-6s explosion turned out to be 20 times more powerful than an atomic bomb. The experiment was considered successful. Scientists were able to achieve an important technological breakthrough. For the first time, lithium hydride was used as a fuel. Within a radius of 4 kilometers from the epicenter of the explosion, the wave destroyed all buildings.

Subsequent tests of the hydrogen bomb in the USSR were based on the experience gained using the RDS-6s. This destructive weapon was not only the most powerful. An important advantage of the bomb was its compactness. The projectile was placed in a Tu-16 bomber. Success allowed Soviet scientists to get ahead of the Americans. In the United States at that time there was a thermonuclear device the size of a house. It was not transportable.

When Moscow announced that the USSR's hydrogen bomb was ready, Washington disputed this information. The main argument of the Americans was the fact that the thermonuclear bomb should be made according to the Teller-Ulam scheme. It was based on the principle of radiation implosion. This project will be implemented in the USSR two years later, in 1955.

Physicist Andrei Sakharov made the greatest contribution to the creation of RDS-6s. The hydrogen bomb was his brainchild - it was he who proposed the revolutionary technical solutions that made it possible to successfully complete tests at the Semipalatinsk test site. Young Sakharov immediately became an academician at the USSR Academy of Sciences, a Hero of Socialist Labor and a laureate of awards and medals. Other scientists also received awards: Yuli Khariton, Kirill Shchelkin, Yakov Zeldovich, Nikolai Dukhov, etc. In 1953, a test of a hydrogen bomb showed that Soviet science can overcome what until recently seemed fiction and fantasy. Therefore, immediately after the successful explosion of the RDS-6s, the development of even more powerful projectiles began.

RDS-37

On November 20, 1955, the next tests of a hydrogen bomb took place in the USSR. This time it was two-stage and corresponded to the Teller-Ulam scheme. The RDS-37 bomb was about to be dropped from an airplane. However, when it took off, it became clear that the tests would have to be carried out in an emergency situation. Contrary to weather forecasters, the weather deteriorated noticeably, causing dense clouds to cover the training ground.

For the first time, experts were forced to land a plane with a thermonuclear bomb on board. For some time there was a discussion at the Central Command Post about what to do next. A proposal to drop a bomb in the mountains nearby was considered, but this option was rejected as too risky. Meanwhile, the plane continued to circle near the test site, running out of fuel.

Zeldovich and Sakharov received the final word. A hydrogen bomb that exploded outside the test site would have led to disaster. The scientists understood the full extent of the risk and their own responsibility, and yet they gave written confirmation that the plane would be safe to land. Finally, the commander of the Tu-16 crew, Fyodor Golovashko, received the command to land. The landing was very smooth. The pilots showed all their skills and did not panic in a critical situation. The maneuver was perfect. The Central Command Post breathed a sigh of relief.

The creator of the hydrogen bomb, Sakharov, and his team survived the tests. The second attempt was scheduled for November 22. On this day everything went without any emergency situations. The bomb was dropped from a height of 12 kilometers. While the shell was falling, the plane managed to move to a safe distance from the epicenter of the explosion. A few minutes later, the nuclear mushroom reached a height of 14 kilometers, and its diameter was 30 kilometers.

The explosion was not without tragic incidents. The shock wave shattered glass at a distance of 200 kilometers, causing several injuries. A girl who lived in a neighboring village also died when the ceiling collapsed on her. Another victim was a soldier who was in a special holding area. The soldier fell asleep in the dugout and died of suffocation before his comrades could pull him out.

Development of the Tsar Bomba

In 1954, the country's best nuclear physicists, under the leadership, began developing the most powerful thermonuclear bomb in the history of mankind. Andrei Sakharov, Viktor Adamsky, Yuri Babaev, Yuri Smirnov, Yuri Trutnev, etc. also took part in this project. Due to its power and size, the bomb became known as the “Tsar Bomba”. Project participants later recalled that this phrase appeared after Khrushchev’s famous statement about “Kuzka’s mother” at the UN. Officially, the project was called AN602.

Over seven years of development, the bomb went through several reincarnations. At first, scientists planned to use components from uranium and the Jekyll-Hyde reaction, but later this idea had to be abandoned due to the danger of radioactive contamination.

Test on Novaya Zemlya

For some time, the Tsar Bomba project was frozen, as Khrushchev was going to the United States, and there was a short pause in the Cold War. In 1961, the conflict between the countries flared up again and in Moscow they again remembered thermonuclear weapons. Khrushchev announced the upcoming tests in October 1961 during the XXII Congress of the CPSU.

On the 30th, a Tu-95B with a bomb on board took off from Olenya and headed for Novaya Zemlya. The plane took two hours to reach its destination. Another Soviet hydrogen bomb was dropped at an altitude of 10.5 thousand meters above nuclear test site"Dry Nose" The shell exploded while still in the air. Arose fire ball, which reached a diameter of three kilometers and almost touched the ground. According to scientists' calculations, the seismic wave from the explosion crossed the planet three times. The impact was felt a thousand kilometers away, and everything living at a distance of a hundred kilometers could receive third-degree burns (this did not happen, since the area was uninhabited).

At that time, the most powerful US thermonuclear bomb was four times less powerful than the Tsar Bomba. The Soviet leadership was pleased with the result of the experiment. Moscow got what it wanted from the next hydrogen bomb. The test demonstrated that the USSR had weapons much more powerful than the United States. Subsequently, the destructive record of the “Tsar Bomba” was never broken. The most powerful hydrogen bomb explosion was a major milestone in the history of science and the Cold War.

Thermonuclear weapons of other countries

British development of the hydrogen bomb began in 1954. The project manager was William Penney, who had previously been a participant in the Manhattan Project in the USA. The British had crumbs of information about the structure of thermonuclear weapons. American allies did not share this information. In Washington, they referred to the atomic energy law passed in 1946. The only exception for the British was permission to observe the tests. They also used aircraft to collect samples left behind by American shell explosions.

At first, London decided to limit itself to creating a very powerful atomic bomb. Thus began the Orange Messenger trials. During them, the most powerful non-thermonuclear bomb in human history was dropped. Its disadvantage was its excessive cost. On November 8, 1957, a hydrogen bomb was tested. The history of the creation of the British two-stage device is an example of successful progress in conditions of lagging behind two superpowers that were arguing among themselves.

The hydrogen bomb appeared in China in 1967, in France in 1968. Thus, today there are five states in the club of countries possessing thermonuclear weapons. Information about the hydrogen bomb in North Korea remains controversial. The head of the DPRK stated that his scientists were able to develop such a projectile. During the tests, seismologists different countries recorded seismic activity caused by a nuclear explosion. But there is still no concrete information about the hydrogen bomb in the DPRK.

American Robert Oppenheimer and Soviet scientist Igor Kurchatov are officially recognized as the fathers of the atomic bomb. But in parallel, deadly weapons were also being developed in other countries (Italy, Denmark, Hungary), so the discovery rightfully belongs to everyone.

The first to tackle this issue were the German physicists Fritz Strassmann and Otto Hahn, who in December 1938 were the first to artificially split atomic nucleus uranium. And six months later, the first reactor was already being built at the Kummersdorf test site near Berlin and uranium ore was urgently purchased from the Congo.

“Uranium Project” - the Germans start and lose

In September 1939, the “Uranium Project” was classified. 22 reputable research centers were invited to participate in the program, and the research was supervised by Minister of Armaments Albert Speer. The construction of an installation for separating isotopes and the production of uranium to extract the isotope from it that supports the chain reaction was entrusted to the IG Farbenindustry concern.

For two years, a group of the venerable scientist Heisenberg studied the possibility of creating a reactor with heavy water. A potential explosive (uranium-235 isotope) could be isolated from uranium ore.

But an inhibitor is needed to slow down the reaction - graphite or heavy water. Choosing the latter option created an insurmountable problem.

The only plant for the production of heavy water, which was located in Norway, was disabled by local resistance fighters after the occupation, and small reserves of valuable raw materials were exported to France.

The rapid implementation of the nuclear program was also hindered by the explosion of an experimental nuclear reactor in Leipzig.

Hitler supported the uranium project as long as he hoped to get more powerful weapon, capable of influencing the outcome of the war he started. After government funding was cut, the work programs continued for some time.

In 1944, Heisenberg managed to create cast uranium plates, and a special bunker was built for the reactor plant in Berlin.

It was planned to complete the experiment to achieve a chain reaction in January 1945, but a month later the equipment was urgently transported to the Swiss border, where it was deployed only a month later. The nuclear reactor contained 664 cubes of uranium weighing 1525 kg. It was surrounded by a graphite neutron reflector weighing 10 tons, and one and a half tons of heavy water were additionally loaded into the core.

On March 23, the reactor finally started working, but the report to Berlin was premature: the reactor did not reach a critical point, and the chain reaction did not occur. Additional calculations showed that the mass of uranium must be increased by at least 750 kg, proportionally adding the amount of heavy water.

But supplies of strategic raw materials were at their limit, as was the fate of the Third Reich. On April 23, the Americans entered the village of Haigerloch, where the tests were carried out. The military dismantled the reactor and transported it to the United States.

The first atomic bombs in the USA

A little later, the Germans began developing the atomic bomb in the USA and Great Britain. It all started with a letter from Albert Einstein and his co-authors, emigrant physicists, sent in September 1939 to US President Franklin Roosevelt.

The appeal emphasized that Nazi Germany was close to creating an atomic bomb.

Stalin first learned about work on nuclear weapons (both allied and adversary) from intelligence officers in 1943. They immediately decided to create a similar project in the USSR. Instructions were issued not only to scientists, but also to intelligence services, for which obtaining any information about nuclear secrets became a major task.

The invaluable information about the developments of American scientists that Soviet intelligence officers were able to obtain significantly advanced the domestic nuclear project. It helped our scientists avoid ineffective search paths and significantly speed up the time frame for achieving the final goal.

Serov Ivan Aleksandrovich - head of the bomb creation operation

Of course, the Soviet government could not ignore the successes of German nuclear physicists. After the war, a group of Soviet physicists, future academicians, were sent to Germany in the uniform of colonels of the Soviet army.

Ivan Serov, the first deputy people's commissar of internal affairs, was appointed head of the operation, this allowed scientists to open any doors.

In addition to their German colleagues, they found reserves of uranium metal. This, according to Kurchatov, shortened the development time of the Soviet bomb by at least a year. More than one ton of uranium and leading nuclear specialists were taken out of Germany by the American military.

Not only chemists and physicists were sent to the USSR, but also qualified labor– mechanics, electricians, glassblowers. Some of the employees were found in prison camps. In total, about 1,000 German specialists worked on the Soviet nuclear project.

German scientists and laboratories on the territory of the USSR in the post-war years

A uranium centrifuge and other equipment, as well as documents and reagents from the von Ardenne laboratory and the Kaiser Institute of Physics were transported from Berlin. As part of the program, laboratories “A”, “B”, “C”, “D” were created, headed by German scientists.

The head of Laboratory “A” was Baron Manfred von Ardenne, who developed a method for gas diffusion purification and separation of uranium isotopes in a centrifuge.

For the creation of such a centrifuge (only on an industrial scale) in 1947 he received the Stalin Prize. At that time, the laboratory was located in Moscow, on the site of the famous Kurchatov Institute. Each German scientist’s team included 5-6 Soviet specialists.

Later, laboratory “A” was taken to Sukhumi, where a physical and technical institute was created on its basis. In 1953, Baron von Ardenne became a Stalin laureate for the second time.

Laboratory B, which conducted experiments in the field of radiation chemistry in the Urals, was headed by Nikolaus Riehl, a key figure in the project. There, in Snezhinsk, the talented Russian geneticist Timofeev-Resovsky, with whom he had been friends back in Germany, worked with him. The successful test of the atomic bomb brought Riehl the star of Hero of Socialist Labor and the Stalin Prize.

Research at Laboratory B in Obninsk was led by Professor Rudolf Pose, a pioneer in the field of nuclear testing. His team managed to create fast neutron reactors, the first nuclear power plant in the USSR, and projects for reactors for submarines.

On the basis of the laboratory, the Physics and Energy Institute named after A.I. was later created. Leypunsky. Until 1957, the professor worked in Sukhumi, then in Dubna, at the Joint Institute of Nuclear Technologies.

Laboratory “G”, located in the Sukhumi sanatorium “Agudzery”, was headed by Gustav Hertz. The nephew of the famous 19th century scientist gained fame after a series of experiments that confirmed the ideas of quantum mechanics and the theory of Niels Bohr.

The results of his productive work in Sukhumi were used to create an industrial installation in Novouralsk, where in 1949 the first Soviet bomb RDS-1 was filled.

The uranium bomb that the Americans dropped on Hiroshima was a cannon type. When creating the RDS-1, domestic nuclear physicists were guided by the Fat Boy - the “Nagasaki bomb”, made of plutonium according to the implosive principle.

In 1951, Hertz was awarded the Stalin Prize for his fruitful work.

German engineers and scientists lived in comfortable houses; they brought their families, furniture, paintings from Germany, they were provided with decent salaries and special food. Did they have the status of prisoners? According to Academician A.P. Aleksandrov, an active participant in the project, they were all prisoners in such conditions.

Having received permission to return to their homeland, the German specialists signed a non-disclosure agreement about their participation in the Soviet nuclear project for 25 years. In the GDR they continued to work in their specialty. Baron von Ardenne was a two-time winner of the German National Prize.

The professor headed the Physics Institute in Dresden, which was created under the auspices of the Scientific Council for the Peaceful Applications of Atomic Energy. The Scientific Council was headed by Gustav Hertz, who received the National Prize of the GDR for his three-volume textbook on atomic physics. Here, in Dresden, at the Technical University, Professor Rudolf Pose also worked.

The participation of German specialists in the Soviet atomic project, as well as the achievements of Soviet intelligence, do not diminish the merits of Soviet scientists who, with their heroic work, created domestic atomic weapons. And yet, without the contribution of each participant in the project, the creation of the nuclear industry and the nuclear bomb would have taken an indefinite period.

Our article is devoted to the history of creation and general principles synthesis of such a device, sometimes called hydrogen. Instead of releasing explosive energy by splitting the nuclei of heavy elements like uranium, it generates even more energy by fusing the nuclei of light elements (such as isotopes of hydrogen) into one heavy one (such as helium).

Why is nuclear fusion preferable?

In a thermonuclear reaction, which consists of the fusion of nuclei participating in it chemical elements, significantly more energy is generated per unit mass of a physical device than in a pure atomic bomb implementing a nuclear fission reaction.

In an atomic bomb, fissile nuclear fuel quickly, under the influence of the energy of detonation of conventional explosives, combines in a small spherical volume, where its so-called critical mass is created, and the fission reaction begins. In this case, many neutrons released from fissile nuclei will cause the fission of other nuclei in the fuel mass, which also release additional neutrons, leading to a chain reaction. It covers no more than 20% of the fuel before the bomb explodes, or perhaps much less if conditions are not ideal: as in the atomic bombs Little Kid dropped on Hiroshima and Fat Man that hit Nagasaki, efficiency (if such a term can be applied to them) apply) were only 1.38% and 13%, respectively.

The fusion (or fusion) of nuclei covers the entire mass of the bomb charge and lasts as long as neutrons can find thermonuclear fuel that has not yet reacted. Therefore, the mass and explosive power of such a bomb are theoretically unlimited. Such a merger can theoretically continue indefinitely. Indeed, the thermonuclear bomb is one of the potential doomsday devices that could destroy all human life.

What is a nuclear fusion reaction?

The fuel for the thermonuclear fusion reaction is hydrogen isotopes deuterium or tritium. The first differs from ordinary hydrogen in that its nucleus, in addition to one proton, also contains a neutron, and the tritium nucleus already has two neutrons. IN natural water There is one deuterium atom for every 7000 hydrogen atoms, but out of its quantity. contained in a glass of water, as a result of a thermonuclear reaction, the same amount of heat can be obtained as from the combustion of 200 liters of gasoline. At a 1946 meeting with politicians, the father of the American hydrogen bomb, Edward Teller, emphasized that deuterium provides more energy per gram of weight than uranium or plutonium, but costs twenty cents per gram compared with several hundred dollars per gram of fission fuel. Tritium does not occur in nature in a free state at all, so it is much more expensive than deuterium, with a market price of tens of thousands of dollars per gram, but the greatest amount of energy is released precisely in the fusion reaction of deuterium and tritium nuclei, in which the nucleus of a helium atom is formed and released neutron carrying away excess energy of 17.59 MeV

D + T → 4 He + n + 17.59 MeV.

This reaction is shown schematically in the figure below.

Is it a lot or a little? As you know, everything is learned by comparison. So, the energy of 1 MeV is approximately 2.3 million times more than that released during the combustion of 1 kg of oil. Consequently, the fusion of only two nuclei of deuterium and tritium releases as much energy as is released during the combustion of 2.3∙10 6 ∙17.59 = 40.5∙10 6 kg of oil. But we are talking about only two atoms. You can imagine how high the stakes were in the second half of the 40s of the last century, when work began in the USA and the USSR, which resulted in a thermonuclear bomb.

How it all began

As early as the summer of 1942, at the beginning of the atomic bomb project in the United States (the Manhattan Project) and later in a similar Soviet program, long before a bomb based on the fission of uranium nuclei was built, the attention of some participants in these programs was drawn to the device, which can use a much more powerful nuclear fusion reaction. In the USA, a supporter of this approach, and even, one might say, its apologist, was the above-mentioned Edward Teller. In the USSR, this direction was developed by Andrei Sakharov, a future academician and dissident.

For Teller, his fascination with thermonuclear fusion during the years of creating the atomic bomb was rather a disservice. As a participant in the Manhattan Project, he persistently called for the redirection of funds to implement his own ideas, the goal of which was a hydrogen and thermonuclear bomb, which did not please the leadership and caused tension in relations. Since at that time the thermonuclear direction of research was not supported, after the creation of the atomic bomb Teller left the project and began teaching, as well as researching elementary particles.

However, the outbreak of the Cold War, and most of all the creation and successful testing of the Soviet atomic bomb in 1949, became a new chance for the ardent anti-communist Teller to realize his scientific ideas. He returns to the Los Alamos laboratory, where the atomic bomb was created, and, together with Stanislav Ulam and Cornelius Everett, begins calculations.

The principle of a thermonuclear bomb

In order for the nuclear fusion reaction to begin, the bomb charge must be instantly heated to a temperature of 50 million degrees. The thermonuclear bomb scheme proposed by Teller uses for this purpose the explosion of a small atomic bomb, which is located inside the hydrogen casing. It can be argued that there were three generations in the development of her project in the 40s of the last century:

• Teller's variation, known as the "classic super";
• more complex, but also more realistic designs of several concentric spheres;
• the final version of the Teller-Ulam design, which is the basis of all thermonuclear weapon systems operating today.

The thermonuclear bombs of the USSR, whose creation was pioneered by Andrei Sakharov, went through similar design stages. He, apparently, completely independently and independently of the Americans (which cannot be said about the Soviet atomic bomb, created by the joint efforts of scientists and intelligence officers working in the USA) went through all of the above design stages.

The first two generations had the property that they had a succession of interlocking "layers", each of which reinforced some aspect of the previous one, and in some cases feedback was established. There was no clear division between the primary atomic bomb and the secondary thermonuclear one. In contrast, the Teller-Ulam thermonuclear bomb diagram sharply distinguishes between a primary explosion, a secondary explosion, and, if necessary, an additional one.

The device of a thermonuclear bomb according to the Teller-Ulam principle

Many of its details still remain classified, but it is reasonably certain that all thermonuclear weapons currently available are based on the device created by Edward Telleros and Stanislaw Ulam, in which an atomic bomb (i.e. the primary charge) is used to generate radiation, compresses and heats fusion fuel. Andrei Sakharov in the Soviet Union apparently independently came up with a similar concept, which he called the "third idea."

The structure of a thermonuclear bomb in this version is shown schematically in the figure below.

It was cylindrical in shape, with a roughly spherical primary atomic bomb at one end. The secondary thermonuclear charge in the first, not yet industrial samples, was made of liquid deuterium; somewhat later it became solid from a chemical compound called lithium deuteride.

The fact is that industry has long used lithium hydride LiH for balloon-free hydrogen transportation. The developers of the bomb (this idea was first used in the USSR) simply proposed taking its isotope deuterium instead of ordinary hydrogen and combining it with lithium, since it is much easier to make a bomb with a solid thermonuclear charge.

The shape of the secondary charge was a cylinder placed in a container with a lead (or uranium) shell. Between the charges there is a neutron protection shield. The space between the walls of the container with thermonuclear fuel and the bomb body is filled with special plastic, usually polystyrene foam. The bomb body itself is made of steel or aluminum.

These shapes have changed in recent designs such as the one shown below.

In it, the primary charge is flattened, like a watermelon or an American football ball, and the secondary charge is spherical. Such shapes fit much more efficiently into the internal volume of conical missile warheads.

Thermonuclear explosion sequence

When a primary atomic bomb detonates, in the first moments of this process a powerful X-ray radiation (neutron flux) is generated, which is partially blocked by the neutron shield, and is reflected from the inner lining of the housing surrounding the secondary charge, so that the X-rays fall symmetrically across its entire length

On initial stages In a thermonuclear reaction, neutrons from an atomic explosion are absorbed by a plastic filler to prevent the fuel from heating up too quickly.

X-rays initially cause the appearance of a dense plastic foam that fills the space between the housing and the secondary charge, which quickly turns into a plasma state that heats and compresses the secondary charge.

In addition, the X-rays evaporate the surface of the container surrounding the secondary charge. The substance of the container, evaporating symmetrically relative to this charge, acquires a certain impulse directed from its axis, and the layers of the secondary charge, according to the law of conservation of momentum, receive an impulse directed towards the axis of the device. The principle here is the same as in a rocket, only if you imagine that rocket fuel scatters symmetrically from its axis, and the body contracts inward.

As a result of such compression of thermonuclear fuel, its volume decreases thousands of times, and the temperature reaches the level at which the nuclear fusion reaction begins. A thermonuclear bomb explodes. The reaction is accompanied by the formation of tritium nuclei, which merge with deuterium nuclei initially present in the secondary charge.

The first secondary charges were built around a rod core of plutonium, informally called a "candle", which entered into a nuclear fission reaction, i.e., another, additional atomic explosion was carried out in order to further raise the temperature to ensure the start of the nuclear fusion reaction. It is now believed that more efficient compression systems have eliminated the "candle", allowing further miniaturization of bomb design.

Operation Ivy

This was the name given to the tests of American thermonuclear weapons in the Marshall Islands in 1952, during which the first thermonuclear bomb was detonated. It was called Ivy Mike and was built according to the Teller-Ulam standard design. Its secondary thermonuclear charge was placed in a cylindrical container, which was a thermally insulated Dewar flask with thermonuclear fuel in the form of liquid deuterium, along the axis of which a “candle” of 239-plutonium ran. The dewar, in turn, was covered with a layer of 238-uranium weighing more than 5 metric tons, which evaporated during the explosion, providing symmetrical compression of the thermonuclear fuel. The container containing the primary and secondary charges was housed in a steel casing 80 inches wide by 244 inches long with walls 10 to 12 inches thick, the largest example of wrought iron up to that time. The inner surface of the case was lined with sheets of lead and polyethylene to reflect radiation after the explosion of the primary charge and create plasma that heats the secondary charge. The entire device weighed 82 tons. A view of the device shortly before the explosion is shown in the photo below.

The first test of a thermonuclear bomb took place on October 31, 1952. The power of the explosion was 10.4 megatons. Attol Eniwetok, where it was produced, was completely destroyed. The moment of the explosion is shown in the photo below.

The USSR gives a symmetrical answer

The US thermonuclear championship did not last long. On August 12, 1953, the first Soviet thermonuclear bomb RDS-6, developed under the leadership of Andrei Sakharov and Yuli Khariton, was tested at the Semipalatinsk test site. From the description above, it becomes clear that the Americans at Enewetok did not explode the bomb itself, as a type of ready-to-use ammunition, but rather a laboratory device, cumbersome and very imperfect. Soviet scientists, despite the small power of only 400 kg, tested a completely finished ammunition with thermonuclear fuel in the form of solid lithium deuteride, and not liquid deuterium, like the Americans. By the way, it should be noted that only the 6 Li isotope is used in lithium deuteride (this is due to the peculiarities of thermonuclear reactions), and in nature it is mixed with the 7 Li isotope. Therefore, special production facilities were built to separate lithium isotopes and select only 6 Li.

Reaching Power Limit

What followed was a decade of continuous arms race, during which the power of thermonuclear munitions continually increased. Finally, on October 30, 1961, in the USSR over the Novaya Zemlya test site in the air at an altitude of about 4 km, the most powerful thermonuclear bomb that had ever been built and tested, known in the West as the “Tsar Bomba,” was exploded.

This three-stage munition was actually developed as a 101.5-megaton bomb, but the desire to reduce radioactive contamination of the area forced the developers to abandon the third stage with a yield of 50 megatons and reduce the design yield of the device to 51.5 megatons. At the same time, the power of the explosion of the primary atomic charge was 1.5 megatons, and the second thermonuclear stage was supposed to give another 50. The actual power of the explosion was up to 58 megatons. The appearance of the bomb is shown in the photo below.

Its consequences were impressive. Despite the very significant height of the explosion of 4000 m, the incredibly bright fireball with its lower edge almost reached the Earth, and with its upper edge it rose to a height of more than 4.5 km. The pressure below the burst point was six times higher than the peak pressure of the Hiroshima explosion. The flash of light was so bright that it was visible at a distance of 1000 kilometers, despite the cloudy weather. One of the test participants saw a bright flash through dark glasses and felt the effects of the thermal pulse even at a distance of 270 km. A photo of the moment of the explosion is shown below.

It was shown that the power of a thermonuclear charge really has no limitations. After all, it was enough to complete the third stage, and the calculated power would be achieved. But it is possible to increase the number of stages further, since the weight of the Tsar Bomba was no more than 27 tons. The appearance of this device is shown in the photo below.

After these tests, it became clear to many politicians and military men both in the USSR and in the USA that the limit of the nuclear arms race had come and it needed to be stopped.

Modern Russia inherited the nuclear arsenal of the USSR. Today, Russia's thermonuclear bombs continue to serve as a deterrent to those seeking global hegemony. Let's hope they only play their role as a deterrent and never get blown up.

The sun as a fusion reactor

It is well known that the temperature of the Sun, or more precisely its core, reaching 15,000,000 °K, is maintained due to the continuous occurrence of thermonuclear reactions. However, everything that we could glean from the previous text speaks of the explosive nature of such processes. Then why doesn't the Sun explode like a thermonuclear bomb?

The fact is that with a huge share of hydrogen in the solar mass, which reaches 71%, the share of its isotope deuterium, the nuclei of which can only participate in the thermonuclear fusion reaction, is negligible. The fact is that deuterium nuclei themselves are formed as a result of the merger of two hydrogen nuclei, and not just a merger, but with the decay of one of the protons into a neutron, positron and neutrino (so-called beta decay), which is a rare event. In this case, the resulting deuterium nuclei are distributed fairly evenly throughout the volume of the solar core. Therefore, with its enormous size and mass, individual and rare centers of thermonuclear reactions of relatively low power are, as it were, smeared throughout its entire core of the Sun. The heat released during these reactions is clearly not enough to instantly burn out all the deuterium in the Sun, but it is enough to heat it to a temperature that ensures life on Earth.

Hundreds of thousands of famous and forgotten gunsmiths of antiquity fought in search of the ideal weapon, capable of evaporating an enemy army with one click. From time to time, a trace of these searches can be found in fairy tales that more or less plausibly describe a miracle sword or a bow that hits without missing.

Fortunately, technological progress moved so slowly for a long time that the real embodiment of the devastating weapon remained in dreams and oral stories, and later on the pages of books. The scientific and technological leap of the 19th century provided the conditions for the creation of the main phobia of the 20th century. The nuclear bomb, created and tested under real conditions, revolutionized both military affairs and politics.

History of the creation of weapons

For a long time it was believed that the most powerful weapons could only be created using explosives. The discoveries of scientists working with the smallest particles provided scientific evidence that enormous energy can be generated with the help of elementary particles. The first in a series of researchers can be called Becquerel, who in 1896 discovered the radioactivity of uranium salts.

Uranium itself has been known since 1786, but at that time no one suspected its radioactivity. Scientists' work on turn of the 19th century and twentieth centuries revealed not only special physical properties, but also the possibility of obtaining energy from radioactive substances.

The option of making weapons based on uranium was first described in detail, published and patented by French physicists, the Joliot-Curies in 1939.

Despite its value for weapons, the scientists themselves were resolutely against the creation of such a devastating weapon.

Having gone through the Second World War in the Resistance, in the 1950s the couple (Frederick and Irene), realizing the destructive power of war, advocated for general disarmament. They are supported by Niels Bohr, Albert Einstein and other prominent physicists of the time.

Meanwhile, while the Joliot-Curies were busy with the problem of the Nazis in Paris, on the other side of the planet, in America, the world's first nuclear charge was being developed. Robert Oppenheimer, who led the work, was given the broadest powers and enormous resources. The end of 1941 marked the beginning of the Manhattan Project, which ultimately led to the creation of the first combat nuclear warhead.

In the town of Los Alamos, New Mexico, the first production facilities for weapons-grade uranium were erected. Subsequently, similar nuclear centers appeared throughout the country, for example in Chicago, in Oak Ridge, Tennessee, and research was carried out in California. The best forces of the professors of American universities, as well as physicists who fled from Germany, were thrown into creating the bomb.

In the “Third Reich” itself, work on creating a new type of weapon was launched in a manner characteristic of the Fuhrer.

Since “Besnovaty” was more interested in tanks and planes, and the more the better, he did not see much need for a new miracle bomb.

Accordingly, projects not supported by Hitler moved at a snail's pace at best.

When things started to get hot, and it turned out that the tanks and planes were swallowed up by the Eastern Front, the new miracle weapon received support. But it was too late; in conditions of bombing and constant fear of Soviet tank wedges, it was not possible to create a device with a nuclear component.

The Soviet Union was more attentive to the possibility of creating a new type of destructive weapon. In the pre-war period, physicists collected and consolidated general knowledge about nuclear energy and the possibility of creating nuclear weapons. Intelligence worked intensively throughout the entire period of the creation of the nuclear bomb both in the USSR and in the USA. The war played a significant role in slowing down the pace of development, as huge resources went to the front.

True, Academician Igor Vasilyevich Kurchatov, with his characteristic tenacity, promoted the work of all subordinate departments in this direction. Looking ahead a little, it is he who will be tasked with accelerating the development of weapons in the face of the threat of an American strike on the cities of the USSR. It was he, standing in the gravel of a huge machine of hundreds and thousands of scientists and workers, who would be awarded honorary title father of the Soviet nuclear bomb.

World's first tests

But let's return to the American nuclear program. By the summer of 1945, American scientists managed to create the world's first nuclear bomb. Any boy who has made himself or bought a powerful firecracker in a store experiences extraordinary torment, wanting to blow it up as quickly as possible. In 1945, hundreds of American soldiers and scientists experienced the same thing.

On June 16, 1945, the first ever nuclear weapons test and one of the most powerful explosions to date took place in the Alamogordo Desert, New Mexico.

Eyewitnesses watching the explosion from the bunker were amazed by the force with which the charge exploded at the top of the 30-meter steel tower. At first, everything was flooded with light, several times stronger than the sun. Then a fireball rose into the sky, turning into a column of smoke that took shape into the famous mushroom.

As soon as the dust settled, researchers and bomb creators rushed to the site of the explosion. They watched the aftermath from lead-encrusted Sherman tanks. What they saw amazed them; no weapon could cause such damage. The sand melted to glass in some places.

Tiny remains of the tower were also found; in a crater of huge diameter, mutilated and crushed structures clearly illustrated the destructive power.

Damaging factors

This explosion provided the first information about the power of the new weapon, about what it could use to destroy the enemy. These are several factors:

• light radiation, flash, capable of blinding even protected organs of vision;
• shock wave, a dense stream of air moving from the center, destroying most buildings;
• an electromagnetic pulse that disables most equipment and does not allow the use of communications for the first time after the explosion;
• penetrating radiation, the most dangerous factor for those who have taken refuge from other damaging factors, is divided into alpha-beta-gamma irradiation;
• radioactive contamination that can negatively affect health and life for tens or even hundreds of years.

The further use of nuclear weapons, including in combat, showed all the peculiarities of their impact on living organisms and nature. August 6, 1945 was the last day for tens of thousands of residents of the small city of Hiroshima, then known for several important military installations.

The outcome of the war in the Pacific was a foregone conclusion, but the Pentagon believed that the operation on the Japanese archipelago would cost more than a million lives of US Marines. It was decided to kill several birds with one stone, take Japan out of the war, saving on the landing operation, test a new weapon and announce it to the whole world, and, above all, to the USSR.

At one o'clock in the morning, the plane carrying the "Baby" nuclear bomb took off on a mission.

The bomb, dropped over the city, exploded at an altitude of approximately 600 meters at 8.15 am. All buildings located at a distance of 800 meters from the epicenter were destroyed. The walls of only a few buildings, designed for 9 people, survived. magnitude earthquake.

Of every ten people who were within a radius of 600 meters at the time of the bomb explosion, only one could survive. The light radiation turned people into coal, leaving shadow marks on the stone, a dark imprint of the place where the person was. The ensuing blast wave was so strong that it could break glass at a distance of 19 kilometers from the explosion site.

One teenager was knocked out of the house through a window by a dense stream of air; upon landing, the guy saw the walls of the house folding like cards. The blast wave was followed by a fire tornado, destroying those few residents who survived the explosion and did not have time to leave the fire zone. Those at a distance from the explosion began to experience severe malaise, the cause of which was initially unclear to doctors.

Much later, a few weeks later, the term “radiation poisoning” was announced, now known as radiation sickness.

More than 280 thousand people became victims of just one bomb, both directly from the explosion and from subsequent illnesses.

The bombing of Japan with nuclear weapons did not end there. According to the plan, only four to six cities were to be hit, but weather Only Nagasaki was allowed to hit. In this city, more than 150 thousand people became victims of the Fat Man bomb.

Promises by the American government to carry out such attacks until Japan surrendered led to an armistice, and then to the signing of an agreement that ended World War. But for nuclear weapons this was just the beginning.

The most powerful bomb in the world

The post-war period was marked by the confrontation between the USSR bloc and its allies with the USA and NATO. In the 1940s, the Americans seriously considered the possibility of striking the Soviet Union. To contain the former ally, work on creating a bomb had to be accelerated, and already in 1949, on August 29, the US monopoly in nuclear weapons was ended. During the arms race, two nuclear tests deserve the most attention.

Bikini Atoll, known primarily for frivolous swimsuits, literally made a splash throughout the world in 1954 due to the testing of a specially powerful nuclear charge.

Americans, having decided to try new design atomic weapons, did not calculate the charge. As a result, the explosion was 2.5 times more powerful than planned. Residents of nearby islands, as well as the ubiquitous Japanese fishermen, were under attack.

But it was not the most powerful American bomb. In 1960, the B41 nuclear bomb was put into service, but it never underwent full testing due to its power. The force of the charge was calculated theoretically, for fear of exploding such a dangerous weapon at the test site.

The Soviet Union, which loved to be the first in everything, experienced in 1961, otherwise nicknamed “Kuzka’s mother.”

Responding to America's nuclear blackmail, Soviet scientists created the most powerful bomb in the world. Tested on Novaya Zemlya, it left its mark in almost all corners of the globe. According to recollections, a slight earthquake was felt in the most remote corners at the time of the explosion.

The blast wave, of course, having lost all its destructive power, was able to circle the Earth. To date, this is the most powerful nuclear bomb in the world created and tested by mankind. Of course, if his hands were free, Kim Jong-un's nuclear bomb would be more powerful, but he does not have New Earth to test it.

Atomic bomb device

Let's consider a very primitive, purely for understanding, device of an atomic bomb. There are many classes of atomic bombs, but let’s consider three main ones:

• uranium, based on uranium 235, first exploded over Hiroshima;
• plutonium, based on plutonium 239, first exploded over Nagasaki;
• thermonuclear, sometimes called hydrogen, based on heavy water with deuterium and tritium, fortunately not used against the population.

The first two bombs are based on the effect of heavy nuclei fissioning into smaller ones through an uncontrolled nuclear reaction, releasing huge amounts of energy. The third is based on the fusion of hydrogen nuclei (or rather its isotopes of deuterium and tritium) with the formation of helium, which is heavier in relation to hydrogen. For the same bomb weight, the destructive potential of a hydrogen bomb is 20 times greater.

If for uranium and plutonium it is enough to bring together a mass greater than the critical one (at which a chain reaction begins), then for hydrogen this is not enough.

To reliably connect several pieces of uranium into one, a cannon effect is used in which smaller pieces of uranium are shot into larger ones. Gunpowder can also be used, but for reliability, low-power explosives are used.

In a plutonium bomb, to create the necessary conditions for a chain reaction, explosives are placed around ingots containing plutonium. Due to the cumulative effect, as well as the neutron initiator located in the very center (beryllium with several milligrams of polonium) the necessary conditions are achieved.

It has a main charge, which cannot explode on its own, and a fuse. To create conditions for the fusion of deuterium and tritium nuclei, we need unimaginable pressures and temperatures at at least one point. Next, a chain reaction will occur.

To create such parameters, the bomb includes a conventional, but low-power, nuclear charge, which is the fuse. Its detonation creates the conditions for the start of a thermonuclear reaction.

To estimate the power of an atomic bomb, the so-called “TNT equivalent” is used. An explosion is a release of energy, the most famous explosive in the world is TNT (TNT - trinitrotoluene), and all new types of explosives are equated to it. Bomb "Baby" - 13 kilotons of TNT. That is equivalent to 13000.

Bomb "Fat Man" - 21 kilotons, "Tsar Bomba" - 58 megatons of TNT. It’s scary to think of 58 million tons of explosives concentrated in a mass of 26.5 tons, that’s how much weight this bomb has.

The danger of nuclear war and nuclear disasters

Appearing in the midst of terrible war XX century, nuclear weapons became the greatest danger to humanity. Immediately after World War II, the Cold War began, which several times almost escalated into a full-fledged nuclear conflict. The threat of the use of nuclear bombs and missiles by at least one side began to be discussed back in the 1950s.

Everyone understood and understands that there can be no winners in this war.

To contain it, efforts have been and are being made by many scientists and politicians. The University of Chicago, using the input of visiting nuclear scientists, including Nobel laureates, sets the Doomsday Clock a few minutes before midnight. Midnight signifies a nuclear cataclysm, the beginning of a new World War and the destruction of the old world. Over the years, the clock hands fluctuated from 17 to 2 minutes to midnight.

There are also several known major accidents that occurred at nuclear power plants. These disasters have an indirect relation to weapons; nuclear power plants are still different from nuclear bombs, but they perfectly demonstrate the results of using the atom for military purposes. The largest of them:

• 1957, Kyshtym accident, due to a failure in the storage system, an explosion occurred near Kyshtym;
• 1957, Britain, in the north-west of England, security checks were not carried out;
• 1979, USA, due to an untimely detected leak, an explosion and release from a nuclear power plant occurred;
• 1986, tragedy in Chernobyl, explosion of the 4th power unit;
• 2011, accident at the Fukushima station, Japan.

Each of these tragedies left a heavy mark on the fate of hundreds of thousands of people and turned entire areas into non-residential zones with special control.

There were incidents that almost cost the start of a nuclear disaster. Soviet nuclear submarines have repeatedly had reactor-related accidents on board. The Americans dropped a Superfortress bomber with two Mark 39 nuclear bombs on board, with a yield of 3.8 megatons. But the activated “safety system” did not allow the charges to detonate and a disaster was avoided.

Nuclear weapons past and present

Today it is clear to anyone that nuclear war will destroy modern humanity. Meanwhile, the desire to possess nuclear weapons and enter the nuclear club, or rather, burst into it by knocking down the door, still excites the minds of some state leaders.

India and Pakistan created nuclear weapons without permission, and the Israelis are hiding the presence of a bomb.

For some, owning a nuclear bomb is a way to prove their importance on the international stage. For others, it is a guarantee of non-interference by winged democracy or other external factors. But the main thing is that these reserves do not go into business, for which they were really created.

Video

On August 12, 1953, at 7.30 am, the first Soviet hydrogen bomb was tested at the Semipalatinsk test site, which had the service name “Product RDS-6c”. This was the fourth Soviet nuclear weapons test.

The beginning of the first work on the thermonuclear program in the USSR dates back to 1945. Then information was received about research being carried out in the United States on the thermonuclear problem. They were started on the initiative of the American physicist Edward Teller in 1942. The basis was taken by Teller’s concept of thermonuclear weapons, which in the circles of Soviet nuclear scientists was called a “pipe” - a cylindrical container with liquid deuterium, which was supposed to be heated by the explosion of an initiating device such as a conventional atomic bomb. Only in 1950 did the Americans establish that the “pipe” was futile, and they continued to develop other designs. But by this time, Soviet physicists had already independently developed another concept of thermonuclear weapons, which soon - in 1953 - led to success.

An alternative design for a hydrogen bomb was invented by Andrei Sakharov. The bomb was based on the idea of ​​a “puff” and the use of lithium-6 deuteride. Developed at KB-11 (today the city of Sarov, former Arzamas-16, Nizhny Novgorod region), the RDS-6s thermonuclear charge was a spherical system of layers of uranium and thermonuclear fuel, surrounded by a chemical explosive.

To increase the energy release of the charge, tritium was used in its design. The main task in creating such a weapon was to use the energy released during the explosion of an atomic bomb to heat and ignite heavy hydrogen - deuterium, to carry out thermonuclear reactions with the release of energy that can support themselves. To increase the proportion of “burnt” deuterium, Sakharov proposed surrounding the deuterium with a shell of ordinary natural uranium, which was supposed to slow down the expansion and, most importantly, significantly increase the density of deuterium. The phenomenon of ionization compression of thermonuclear fuel, which became the basis of the first Soviet hydrogen bomb, is still called “saccharization.”

Based on the results of work on the first hydrogen bomb, Andrei Sakharov received the title of Hero of Socialist Labor and laureate of the Stalin Prize.

“Product RDS-6s” was made in the form of a transportable bomb weighing 7 tons, which was placed in the bomb hatch of a Tu-16 bomber. For comparison, the bomb created by the Americans weighed 54 tons and was the size of a three-story house.

To assess the destructive effects of the new bomb, a city was built at the Semipalatinsk test site from industrial and administrative buildings. In total, there were 190 different structures on the field. In this test, vacuum intakes of radiochemical samples were used for the first time, which automatically opened under the influence of a shock wave. In total, 500 different measuring, recording and filming instruments installed in underground casemates and durable ground structures. Aviation technical support for the tests - measuring the pressure of the shock wave on the aircraft in the air at the time of the explosion of the product, taking air samples from the radioactive cloud, and aerial photography of the area was carried out by a special flight unit. The bomb was detonated remotely by sending a signal from a remote control located in the bunker.

It was decided to carry out an explosion on a steel tower 40 meters high, the charge was located at a height of 30 meters. The radioactive soil from previous tests was removed to a safe distance, special structures were built in their own places on old foundations, and a bunker was built 5 meters from the tower to install equipment developed at the Institute of Chemical Physics of the USSR Academy of Sciences that recorded thermonuclear processes.

Military equipment from all branches of the military was installed on the field. During the tests, all experimental structures within a radius of up to four kilometers were destroyed. A hydrogen bomb explosion could completely destroy a city 8 kilometers across. The environmental consequences of the explosion were terrifying: the first explosion accounted for 82% strontium-90 and 75% cesium-137.

The power of the bomb reached 400 kilotons, 20 times more than the first atomic bombs in the USA and USSR.

The work to create the hydrogen bomb became the world's first intellectual "battle of wits" on a truly global scale. The creation of the hydrogen bomb initiated the emergence of completely new scientific directions - the physics of high-temperature plasma, the physics of ultra-high energy densities, and the physics of anomalous pressures. For the first time in human history, mathematical modeling was used on a large scale.

Work on the “RDS-6s product” created a scientific and technical basis, which was then used in the development of an incomparably more advanced hydrogen bomb of a fundamentally new type - a two-stage hydrogen bomb.

The hydrogen bomb of Sakharov’s design not only became a serious counter-argument in the political confrontation between the USA and the USSR, but also served as the reason for the rapid development of Soviet cosmonautics in those years. It was after successful nuclear tests that the Korolev Design Bureau received an important government task to develop an intercontinental ballistic missile to deliver the created charge to the target. Subsequently, the rocket, called the “seven”, launched the first artificial Earth satellite into space, and it was on it that the first cosmonaut of the planet, Yuri Gagarin, launched.

The material was prepared based on information from open sources