The first one invented nuclear power. Who really created the atomic bomb? Atomic bomb device

Under what conditions and with what efforts did the country, which survived the most terrible war of the twentieth century, create its atomic shield?
Almost seven decades ago, October 29, 1949, Presidium Supreme Council The USSR issued four top-secret decrees awarding 845 people the titles of Heroes of Socialist Labor, the Order of Lenin, the Red Banner of Labor and the Badge of Honor. In none of them was it said in relation to any of the recipients what exactly he was awarded for: the standard wording “for exceptional services to the state while performing a special task” appeared everywhere. Even for the Soviet Union, accustomed to secrecy, this was a rare occurrence. Meanwhile, the recipients themselves knew very well, of course, what kind of “exceptional merits” were meant. All 845 people were, to a greater or lesser extent, directly connected with the creation of the first nuclear bomb of the USSR.

It was not strange for the awardees that both the project itself and its success were shrouded in a thick veil of secrecy. After all, they all knew well that they owed their success to a large extent to the courage and professionalism of Soviet intelligence officers, who for eight years had been supplying scientists and engineers with top-secret information from abroad. And such a high assessment that the creators of the Soviet atomic bomb deserved was not exaggerated. As one of the creators of the bomb, academician Yuli Khariton, recalled, at the presentation ceremony Stalin suddenly said: “If we had been one to a year and a half late, we would probably have tried this charge on ourselves.” And this is not an exaggeration...

Atomic bomb sample... 1940

The Soviet Union came to the idea of ​​creating a bomb that uses the energy of a nuclear chain reaction almost simultaneously with Germany and the United States. The first officially considered project of this type of weapon was presented in 1940 by a group of scientists from the Kharkov Institute of Physics and Technology under the leadership of Friedrich Lange. It was in this project that for the first time in the USSR, a scheme for detonating conventional explosives, which later became classic for all nuclear weapons, was proposed, due to which two subcritical masses of uranium are almost instantly formed into a supercritical one.

The project received negative reviews and was not considered further. But the work on which it was based continued, and not only in Kharkov. At least four large institutes were involved in atomic issues in the pre-war USSR - in Leningrad, Kharkov and Moscow, and the work was supervised by the Chairman of the Council of People's Commissars, Vyacheslav Molotov. Soon after the presentation of Lange's project, in January 1941, the Soviet government made a logical decision to classify domestic atomic research. It was clear that they could really lead to the creation of a new type of powerful technology, and such information should not be scattered, especially since it was at that time that the first intelligence data on the American atomic project was received - and Moscow did not want to risk its own.

The natural course of events was interrupted by the beginning of the Great Patriotic War. But, despite the fact that all Soviet industry and science were very quickly transferred to a military footing and began to provide the army with the most urgent developments and inventions, strength and means were also found to continue the atomic project. Although not right away. The resumption of research must be counted from the resolution of the State Defense Committee of February 11, 1943, which stipulated the beginning practical work to create an atomic bomb.

Project "Enormoz"

By this time the Soviet foreign intelligence She was already working hard to obtain information on the Enormoz project - this is how the American atomic project was called in operational documents. The first meaningful data indicating that the West was seriously engaged in the creation of uranium weapons came from the London station in September 1941. And at the end of the same year, a message comes from the same source that America and Great Britain agreed to coordinate the efforts of their scientists in the field of atomic energy research. In war conditions, this could only be interpreted in one way: the Allies are working to create atomic weapons. And in February 1942, intelligence received documentary evidence that Germany was actively doing the same thing.

As the efforts of Soviet scientists, working according to their own plans, advanced, intelligence work intensified to obtain information about the American and British atomic projects. In December 1942, it became finally clear that the United States was clearly ahead of Britain in this area, and the main efforts were focused on obtaining data from overseas. In fact, every step of the participants in the “Manhattan Project,” as the work on creating the atomic bomb in the United States was called, was tightly controlled by Soviet intelligence. Suffice it to say that the most detailed information about the structure of the first real atomic bomb was received in Moscow less than two weeks after it was assembled in America.

That is why the boastful message of the new US President Harry Truman, who decided to dumbfound Stalin by Potsdam Conference The announcement that America has a new weapon of unprecedented destructive power did not provoke the reaction that the American was counting on. Soviet leader He listened to him calmly, nodded, and said nothing. Foreigners were sure that Stalin simply did not understand anything. In fact, the leader of the USSR sensibly appreciated Truman’s words and that same day in the evening demanded that Soviet specialists speed up work on creating their own atomic bomb as much as possible. But it was no longer possible to overtake America. Less than a month later, the first atomic mushroom grew over Hiroshima, and three days later - over Nagasaki. And over the Soviet Union hung the shadow of a new, nuclear war, and not with anyone, but with former allies.

Time forward!

Now, seventy years later, no one is surprised that the Soviet Union received the much-needed reserve of time to create its own superbomb, despite sharply deteriorating relations with ex-partners in the anti-Hitler coalition. After all, already on March 5, 1946, six months after the first atomic bombings, Winston Churchill’s famous Fulton speech was made, which marked the beginning cold war. But, according to the plans of Washington and its allies, it was supposed to develop into a hot one later - at the end of 1949. After all, as it was hoped overseas, the USSR was not supposed to receive its own atomic weapons before the mid-1950s, which means there was nowhere to rush.

Atomic bomb tests. Photo: U.S. Air Force/AR

From high today It seems surprising that there is a coincidence between the date of the start of the new world war - more precisely, one of the dates of one of the main plans, Fleetwood - and the date of the test of the first Soviet nuclear bomb: 1949. But in reality everything is natural. The foreign policy situation was heating up quickly, the former allies were speaking more and more harshly to each other. And in 1948, it became absolutely clear that Moscow and Washington, apparently, would no longer be able to come to an agreement with each other. From here you need to count down the time until the start new war: a year is the deadline during which countries that have recently emerged from a colossal war can fully prepare for a new one, moreover, with a state that bore the brunt of the Victory on its shoulders. Even the nuclear monopoly did not give the United States the opportunity to shorten the preparation for war.

Foreign “accents” of the Soviet atomic bomb

We all understood this perfectly well. Since 1945, all work related to the atomic project has sharply intensified. During the first two post-war years The USSR, tormented by the war and having lost a considerable part of its industrial potential, managed to create a colossal nuclear industry from scratch. Future nuclear centers emerged, such as Chelyabinsk-40, Arzamas-16, Obninsk, and large scientific institutes and production facilities emerged.

Not so long ago, a common point of view on the Soviet atomic project was this: they say, if not for intelligence, USSR scientists would not have been able to create any atomic bomb. In reality, everything was far from being as clear as the revisionists of Russian history tried to show. In fact, the data obtained by Soviet intelligence about the American atomic project allowed our scientists to avoid many mistakes that their American colleagues who had gone ahead inevitably had to make (whom, let us recall, the war did not seriously interfere with their work: the enemy did not invade US territory, and the country did not lose a few months half of the industry). In addition, intelligence data undoubtedly helped Soviet specialists evaluate the most advantageous designs and technical solutions, which allowed them to assemble their own, more advanced atomic bomb.

And if we talk about the degree of foreign influence on the Soviet nuclear project, then, rather, we need to remember the several hundred German nuclear specialists who worked at two secret facilities near Sukhumi - in the prototype of the future Sukhumi Institute of Physics and Technology. They really helped greatly to advance work on the “product” - the first atomic bomb of the USSR, so much so that many of them were awarded Soviet orders by the same secret decrees of October 29, 1949. Most of these specialists went back to Germany five years later, settling mostly in the GDR (although there were also some who went to the West).

Objectively speaking, the first Soviet atomic bomb had, so to speak, more than one “accent.” After all, it was born as a result of a colossal cooperation of efforts of many people - both those who worked on the project of their own free will, and those who were involved in the work as prisoners of war or interned specialists. But the country, which at all costs needed to quickly obtain weapons that would equalize its chances with the ex-allies who were rapidly turning into mortal enemies, had no time for sentimentality.

Russia does it itself!

In the documents relating to the creation of the first nuclear bomb of the USSR, the term “product”, which later became popular, had not yet been encountered. Much more often it was officially called a “special jet engine,” or RDS for short. Although, of course, there was nothing reactive in the work on this design: the whole point was only in the strictest requirements of secrecy.

With the light hand of Academician Yuli Khariton, the unofficial decoding “Russia does it itself” very quickly became attached to the abbreviation RDS. There was a considerable amount of irony in this, since everyone knew how much the information obtained by intelligence had given our nuclear scientists, but also a large share of truth. After all, if the design of the first Soviet nuclear bomb was very similar to the American one (simply because the most optimal one was chosen, and the laws of physics and mathematics do not have national characteristics), then, say, the ballistic body and electronic filling of the first bomb were a purely domestic development.

When work on the Soviet atomic project had progressed far enough, the USSR leadership formulated tactical and technical requirements for the first atomic bombs. It was decided to simultaneously develop two types: an implosion-type plutonium bomb and a cannon-type uranium bomb, similar to that used by the Americans. The first received the RDS-1 index, the second, respectively, RDS-2.

According to the plan, RDS-1 was to be submitted for state tests by explosion in January 1948. But these deadlines could not be met: problems arose with the production and processing of the required amount of weapons-grade plutonium for its equipment. It was received only a year and a half later, in August 1949, and immediately went to Arzamas-16, where the first Soviet atomic bomb was almost ready. Within a few days, specialists from the future VNIIEF completed the assembly of the “product”, and it went to the Semipalatinsk test site for testing.

The first rivet of Russia's nuclear shield

The first nuclear bomb of the USSR was detonated at seven o'clock in the morning on August 29, 1949. Almost a month passed before overseas people recovered from the shock caused by intelligence reports about the successful testing of our own “big stick” in our country. Only on September 23, Harry Truman, who had not so long ago boastfully informed Stalin about America’s successes in creating atomic weapons, made a statement that the same type of weapons was now available in the USSR.

Presentation of a multimedia installation in honor of the 65th anniversary of the creation of the first Soviet atomic bomb. Photo: Geodakyan Artem / TASS

Oddly enough, Moscow was in no hurry to confirm the Americans’ statements. On the contrary, TASS actually came out with a refutation of the American statement, arguing that the whole point is in the colossal scale of construction in the USSR, in which blasting operations with the use of latest technologies. True, at the end of the Tassov statement there was a more than transparent hint about possessing its own nuclear weapons. The agency reminded everyone interested that back on November 6, 1947, USSR Foreign Minister Vyacheslav Molotov stated that no secret of the atomic bomb had existed for a long time.

And this was twice true. By 1947, no information about atomic weapons was any longer a secret for the USSR, and by the end of the summer of 1949, it was no longer a secret to anyone that the Soviet Union had restored strategic parity with its main rival, the United States. A parity that has persisted for six decades. Parity, which helps to maintain nuclear shield Russia and which began on the eve of the Great Patriotic War.

The American Robert Oppenheimer and the Soviet scientist Igor Kurchatov are usually called the fathers of the atomic bomb. But considering that work on the deadly was carried out in parallel in four countries and, in addition to scientists from these countries, people from Italy, Hungary, Denmark, etc., took part in it, the resulting bomb can rightly be called the brainchild of different peoples.

The Germans were the first to get down to business. In December 1938, their physicists Otto Hahn and Fritz Strassmann were the first in the world to artificially split the nucleus of a uranium atom. In April 1939, the German military leadership received a letter from Hamburg University professors P. Harteck and W. Groth, which indicated the fundamental possibility of creating a new type of highly effective explosive. Scientists wrote: “The country that is the first to practically master the achievements of nuclear physics will acquire absolute superiority over others.” And now the Imperial Ministry of Science and Education is holding a meeting on the topic “On a self-propagating (that is, chain) nuclear reaction.” Among the participants is Professor E. Schumann, head of the research department of the Armament Directorate of the Third Reich. Without delay, we moved from words to deeds. Already in June 1939, construction of Germany's first reactor plant began at the Kummersdorf test site near Berlin. A law was passed banning the export of uranium outside Germany, and urgent purchases were made in the Belgian Congo. a large number of uranium ore.

Germany starts and... loses

On September 26, 1939, when war was already raging in Europe, it was decided to classify all work related to the uranium problem and the implementation of the program, called the “Uranium Project”. The scientists involved in the project were initially very optimistic: they believed it was possible to create nuclear weapons during a year. They were wrong, as life has shown.

22 organizations were involved in the project, including such well-known scientific centers, as the Kaiser Wilhelm Society Physics Institute, Institute physical chemistry University of Hamburg, Physics Institute of the Higher Technical School in Berlin, Physico-Chemical Institute of the University of Leipzig and many others. The project was personally supervised by the Reich Minister of Armaments Albert Speer. The IG Farbenindustry concern was entrusted with the production of uranium hexafluoride, from which it is possible to extract the uranium-235 isotope, capable of maintaining a chain reaction. The same company was also entrusted with the construction of an isotope separation plant. Such venerable scientists as Heisenberg, Weizsäcker, von Ardenne, Riehl, Pose, Nobel laureate Gustav Hertz and others.

Over the course of two years, Heisenberg's group carried out the research necessary to create a nuclear reactor using uranium and heavy water. It was confirmed that only one of the isotopes, namely uranium-235, contained in very small concentrations in ordinary uranium ore, can serve as an explosive. The first problem was how to isolate it from there. The starting point of the bomb program was atomic reactor, which required graphite or heavy water as a reaction moderator. German physicists chose water, thereby creating for themselves serious problem. After the occupation of Norway, the world's only heavy water production plant at that time passed into the hands of the Nazis. But there, at the beginning of the war, the supply of the product needed by physicists was only tens of kilograms, and even they did not go to the Germans - the French stole valuable products literally from under the noses of the Nazis. And in February 1943, British commandos sent to Norway, with the help of local resistance fighters, put the plant out of commission. The implementation of Germany's nuclear program was under threat. The misfortunes of the Germans did not end there: an experimental nuclear reactor exploded in Leipzig. The uranium project was supported by Hitler only as long as there was hope of obtaining super-powerful weapons before the end of the war he started. Heisenberg was invited by Speer and asked directly: “When can we expect the creation of a bomb capable of being suspended from a bomber?” The scientist was honest: “I believe it will take several years of hard work, in any case, the bomb will not be able to influence the outcome of the current war.” The German leadership rationally considered that there was no point in forcing events. Let the scientists work quietly - you'll see they'll be in time for the next war. As a result, Hitler decided to concentrate scientific, production and financial resources only on projects that would give the fastest return in the creation of new types of weapons. Government funding for the uranium project was curtailed. Nevertheless, the work of scientists continued.

In 1944, Heisenberg received cast uranium plates for a large reactor plant, for which a special bunker was already being built in Berlin. The last experiment to achieve a chain reaction was scheduled for January 1945, but on January 31 all the equipment was hastily dismantled and sent from Berlin to the village of Haigerloch near the Swiss border, where it was deployed only at the end of February. The reactor contained 664 cubes of uranium with a total weight of 1525 kg, surrounded by a graphite moderator-neutron reflector weighing 10 tons. In March 1945, an additional 1.5 tons of heavy water was poured into the core. On March 23, Berlin was reported that the reactor was operational. But the joy was premature - the reactor did not reach the critical point, the chain reaction did not start. After recalculations, it turned out that the amount of uranium must be increased by at least 750 kg, proportionally increasing the mass of heavy water. But there were no more reserves of either one or the other. The end of the Third Reich was inexorably approaching. On April 23, Haigerloch was entered American troops. The reactor was dismantled and transported to the USA.

Meanwhile overseas

In parallel with the Germans (with only a slight lag), the development of atomic weapons began in England and the USA. They began with a letter sent in September 1939 by Albert Einstein to US President Franklin Roosevelt. The initiators of the letter and the authors of most of the text were physicists-emigrants from Hungary Leo Szilard, Eugene Wigner and Edward Teller. The letter drew the president's attention to the fact that Nazi Germany was conducting active research, as a result of which it might soon acquire an atomic bomb.

In the USSR, the first information about the work carried out by both the allies and the enemy was reported to Stalin by intelligence back in 1943. A decision was immediately made to launch similar work in the Union. Thus began the Soviet atomic project. Not only scientists received assignments, but also intelligence officers, for whom the spoils nuclear secrets has become a major task.

The most valuable information about the work on the atomic bomb in the United States, obtained by intelligence, greatly helped the advancement of the Soviet nuclear project. The scientists participating in it were able to avoid dead-end search paths, thereby significantly accelerating the achievement of the final goal.

Experience of recent enemies and allies

Naturally, the Soviet leadership could not remain indifferent to German atomic developments. At the end of the war, a group of Soviet physicists was sent to Germany, among whom were future academicians Artsimovich, Kikoin, Khariton, Shchelkin. Everyone was camouflaged in the uniform of Red Army colonels. The operation was led by First Deputy People's Commissar of Internal Affairs Ivan Serov, which opened any doors. In addition to the necessary German scientists, the “colonels” found tons of uranium metal, which, according to Kurchatov, shortened the work on the Soviet bomb by at least a year. The Americans also removed a lot of uranium from Germany, taking along the specialists who worked on the project. And in the USSR, in addition to physicists and chemists, they sent mechanics, electrical engineers, and glassblowers. Some were found in prisoner of war camps. For example, Max Steinbeck, the future Soviet academician and vice-president of the Academy of Sciences of the GDR, was taken away when, at the whim of the camp commander, he was manufacturing sundial. In total, at least 1,000 German specialists worked on the nuclear project in the USSR. The von Ardenne laboratory with a uranium centrifuge, equipment from the Kaiser Institute of Physics, documentation, and reagents were completely removed from Berlin. As part of the atomic project, laboratories “A”, “B”, “C” and “D” were created, the scientific directors of which were scientists who arrived from Germany.

Laboratory “A” was led by Baron Manfred von Ardenne, a talented physicist who developed a method of gas diffusion purification and separation of uranium isotopes in a centrifuge. At first, his laboratory was located on Oktyabrsky Pole in Moscow. Each German specialist was assigned five or six Soviet engineers. Later the laboratory moved to Sukhumi, and over time the famous Kurchatov Institute grew up on Oktyabrsky Field. In Sukhumi, on the basis of the von Ardenne laboratory, the Sukhumi Institute of Physics and Technology was formed. In 1947, Ardenne was awarded the Stalin Prize for creating a centrifuge for purifying uranium isotopes in industrial scale. Six years later, Ardenne became a two-time Stalinist laureate. He lived with his wife in a comfortable mansion, his wife played music on a piano brought from Germany. Others were not offended either German specialists: they came with their families, brought with them furniture, books, paintings, and were provided with good salaries and food. Were they prisoners? Academician A.P. Aleksandrov, himself an active participant in the atomic project, noted: “Of course, the German specialists were prisoners, but we ourselves were prisoners.”

Nikolaus Riehl, a native of St. Petersburg who moved to Germany in the 1920s, became the head of Laboratory B, which conducted research in the field of radiation chemistry and biology in the Urals (now the city of Snezhinsk). Here, Riehl worked with his old friend from Germany, the outstanding Russian biologist-geneticist Timofeev-Resovsky (“Bison” based on the novel by D. Granin).

Having received recognition in the USSR as a researcher and talented organizer who knows how to find effective solutions complex problems, Dr. Riehl became one of the key figures in the Soviet atomic project. After successful test Soviet bomb he became a Hero of Socialist Labor and a laureate of the Stalin Prize.

The work of Laboratory "B", organized in Obninsk, was headed by Professor Rudolf Pose, one of the pioneers in the field of nuclear research. Under his leadership, fast neutron reactors were created, the first nuclear power plant in the Union, and the design of reactors for submarines began. The facility in Obninsk became the basis for the organization of the Physics and Energy Institute named after A.I. Leypunsky. Pose worked until 1957 in Sukhumi, then at the Joint Institute for Nuclear Research in Dubna.

The head of Laboratory "G", located in the Sukhumi sanatorium "Agudzery", was Gustav Hertz, the nephew of the famous physicist of the 19th century, himself a famous scientist. He was recognized for a series of experiments that confirmed Niels Bohr's theory of the atom and quantum mechanics. The results of his very successful activities in Sukhumi were later used at an industrial installation built in Novouralsk, where in 1949 the filling for the first Soviet atomic bomb RDS-1 was developed. For his achievements within the framework of the atomic project, Gustav Hertz was awarded the Stalin Prize in 1951.

German specialists who received permission to return to their homeland (naturally, to the GDR) signed a non-disclosure agreement for 25 years about their participation in the Soviet atomic project. In Germany they continued to work in their specialty. Thus, Manfred von Ardenne, twice awarded the National Prize of the GDR, served as director Physical Institute in Dresden, created under the auspices Scientific Council on the peaceful uses of atomic energy, led by Gustav Hertz. Hertz also received a national prize as the author of a three-volume textbook on nuclear physics. There, in Dresden, in Technical University, Rudolf Pose also worked.

The participation of German scientists in the atomic project, as well as the successes of intelligence officers, in no way detract from the merits of Soviet scientists, whose selfless work ensured the creation of domestic atomic weapons. However, it must be admitted that without the contribution of both of them, the creation of the nuclear industry and atomic weapons in the USSR would have dragged on for many years.

Little Boy
The American uranium bomb that destroyed Hiroshima had a cannon design. Soviet nuclear scientists, when creating the RDS-1, were guided by the “Nagasaki bomb” - Fat Boy, made of plutonium using an implosion design.

Manfred von Ardenne, who developed a method for gas diffusion purification and separation of uranium isotopes in a centrifuge.

Operation Crossroads was a series of atomic bomb tests conducted by the United States at Bikini Atoll in the summer of 1946. The goal was to test the effect of atomic weapons on ships.

Help from overseas

In 1933, German communist Klaus Fuchs fled to England. Having received a degree in physics from the University of Bristol, he continued to work. In 1941, Fuchs reported his participation in atomic research to Soviet intelligence agent Jürgen Kuchinsky, who informed the Soviet ambassador Ivan Maisky. He instructed the military attaché to urgently establish contact with Fuchs, who was going to be transported to the United States as part of a group of scientists. Fuchs agreed to work for Soviet intelligence. Many Soviet illegal intelligence officers were involved in working with him: the Zarubins, Eitingon, Vasilevsky, Semenov and others. As a result of their active work, already in January 1945 the USSR had a description of the design of the first atomic bomb. At the same time, the Soviet station in the United States reported that the Americans would need at least one year, but no more than five years, to create a significant arsenal of atomic weapons. The report also said that the first two bombs could be detonated within a few months.

Pioneers of nuclear fission

K. A. Petrzhak and G. N. Flerov
In 1940, in the laboratory of Igor Kurchatov, two young physicists discovered a new, very unique type of radioactive decay of atomic nuclei - spontaneous fission.

Otto Hahn
In December 1938, German physicists Otto Hahn and Fritz Strassmann were the first in the world to artificially split the nucleus of a uranium atom.

Nuclear weapons - weapons mass destruction explosive action, based on the use of fission energy of heavy nuclei of some isotopes of uranium and plutonium, or in thermonuclear reactions of synthesis of light nuclei of hydrogen isotopes of deuterium and tritium into heavier ones, for example, nuclei of helium isotopes.

Warheads of missiles and torpedoes, aircraft and depth charges, artillery shells and mines can be equipped with nuclear charges. Based on their power, nuclear weapons are divided into ultra-small (less than 1 kt), small (1-10 kt), medium (10-100 kt), large (100-1000 kt) and super-large (more than 1000 kt). Depending on the tasks being solved, it is possible to use nuclear weapons in the form of underground, ground, air, underwater and surface explosions. The characteristics of the destructive effect of nuclear weapons on the population are determined not only by the power of the ammunition and the type of explosion, but also by the type nuclear device. Depending on the charge, they are distinguished: atomic weapons, which are based on the fission reaction; thermonuclear weapons - when using a fusion reaction; combined charges; neutron weapons.

The only fissile substance found in nature in appreciable quantities is the isotope of uranium with a nuclear mass of 235 atomic mass units (uranium-235). The content of this isotope in natural uranium is only 0.7%. The remainder is uranium-238. Since the chemical properties of the isotopes are exactly the same, separating uranium-235 from natural uranium requires a rather complex process of isotope separation. The result can be highly enriched uranium containing about 94% uranium-235, which is suitable for use in nuclear weapons.

Fissile substances can be produced artificially, and the least difficult from a practical point of view is the production of plutonium-239, which is formed as a result of the capture of a neutron by a uranium-238 nucleus (and the subsequent chain of radioactive decays of intermediate nuclei). A similar process can be carried out in nuclear reactor, operating on natural or slightly enriched uranium. In the future, plutonium can be separated from spent reactor fuel in the process of chemical reprocessing of the fuel, which is noticeably simpler than the isotope separation process carried out when producing weapons-grade uranium.

To create nuclear explosive devices, other fissile substances can be used, for example, uranium-233, obtained by irradiation of thorium-232 in a nuclear reactor. However, only uranium-235 and plutonium-239 have found practical use, primarily due to the relative ease of obtaining these materials.

The possibility of practical use of the energy released during nuclear fission is due to the fact that the fission reaction can have a chain, self-sustaining nature. Each fission event produces approximately two secondary neutrons, which, when captured by the nuclei of the fissile material, can cause them to fission, which in turn leads to the formation of even more neutrons. When special conditions are created, the number of neutrons, and therefore fission events, increases from generation to generation.

The first nuclear explosive device was detonated by the United States on July 16, 1945 in Alamogordo, New Mexico. The device was a plutonium bomb that used a directed explosion to create criticality. The power of the explosion was about 20 kt. In the USSR, the first nuclear explosive device similar to the American one exploded on August 29, 1949.

The history of the creation of nuclear weapons.

In early 1939, the French physicist Frédéric Joliot-Curie concluded that a chain reaction was possible that would lead to an explosion of monstrous destructive force and that uranium could become a source of energy as an ordinary explosive. This conclusion became the impetus for developments in the creation of nuclear weapons. Europe was on the eve of the Second World War, and the potential possession of such powerful weapons gave any owner enormous advantages. Physicists from Germany, England, the USA, and Japan worked on the creation of atomic weapons.

By the summer of 1945, the Americans managed to assemble two atomic bombs, called “Baby” and “Fat Man”. The first bomb weighed 2,722 kg and was filled with enriched Uranium-235.

The "Fat Man" bomb with a charge of Plutonium-239 with a power of more than 20 kt had a mass of 3175 kg.

US President G. Truman became the first political leader to decide to use nuclear bombs. The first goals for nuclear strikes Japanese cities were chosen (Hiroshima, Nagasaki, Kokura, Niigata). From a military point of view, there was no need for such bombing of densely populated Japanese cities.

On the morning of August 6, 1945, there was a clear, cloudless sky over Hiroshima. As before, the approach of two American planes from the east (one of them was called Enola Gay) at an altitude of 10-13 km did not cause alarm (since they appeared in the sky of Hiroshima every day). One of the planes dived and dropped something, and then both planes turned and flew away. The dropped object slowly descended by parachute and suddenly exploded at an altitude of 600 m above the ground. It was the Baby bomb. On August 9, another bomb was dropped over the city of Nagasaki.

The total loss of life and the scale of destruction from these bombings are characterized by the following figures: 300 thousand people died instantly from thermal radiation (temperature about 5000 degrees C) and the shock wave, another 200 thousand were injured, burned, radiation sickness. On an area of ​​12 sq. km, all buildings were completely destroyed. In Hiroshima alone, out of 90 thousand buildings, 62 thousand were destroyed.

After the American atomic bombings, on August 20, 1945, by order of Stalin, a special committee on atomic energy was formed under the leadership of L. Beria. The committee included prominent scientists A.F. Ioffe, P.L. Kapitsa and I.V. Kurchatov. A communist by conviction, scientist Klaus Fuchs, a prominent employee of the American nuclear center in Los Alamos, provided a great service to Soviet nuclear scientists. During 1945-1947, he transmitted information on practical and theoretical issues of creating atomic and hydrogen bombs four times, which accelerated their appearance in the USSR.

In 1946 - 1948, the nuclear industry was created in the USSR. A test site was built in the area of ​​Semipalatinsk. In August 1949, the first Soviet nuclear device was detonated there. Before this, US President Henry Truman was informed that the Soviet Union had mastered the secret of nuclear weapons, but the Soviet Union would not create a nuclear bomb until 1953. This message caused the US ruling circles to want to start a preventive war as quickly as possible. The Troyan plan was developed, which envisaged the start of hostilities at the beginning of 1950. At that time, the United States had 840 strategic bombers and over 300 atomic bombs.

Damaging factors nuclear explosion are: shock wave, light radiation, penetrating radiation, radioactive contamination and electromagnetic pulse.

Shock wave. Basic damaging factor nuclear explosion. About 60% of the energy of a nuclear explosion is spent on it. It is an area of ​​sharp air compression, spreading in all directions from the explosion site. The damaging effect of a shock wave is characterized by the magnitude of excess pressure. Excess pressure is the difference between the maximum pressure at the shock wave front and the normal atmospheric pressure ahead of it. It is measured in kilopascals - 1 kPa = 0.01 kgf/cm2.

With excess pressure of 20-40 kPa, unprotected people can get mild injuries. Exposure to a shock wave with an excess pressure of 40-60 kPa leads to moderate damage. Severe injuries occur when excess pressure exceeds 60 kPa and are characterized by severe contusions of the entire body, fractures of the limbs, and ruptures of internal parenchymal organs. Extremely severe injuries, often fatal, are observed at excess pressure above 100 kPa.

Light radiation is a stream of radiant energy, including visible ultraviolet and infrared rays.

Its source is a luminous area formed by the hot products of the explosion. Light radiation spreads almost instantly and lasts, depending on the power of the nuclear explosion, up to 20 s. Its strength is such that, despite its short duration, it can cause fires, deep skin burns and damage to the organs of vision in people.

Light radiation does not penetrate through opaque materials, so any barrier that can create a shadow protects against the direct action of light radiation and prevents burns.

Light radiation is significantly weakened in dusty (smoky) air, fog, and rain.

Penetrating radiation.

This is a stream of gamma radiation and neutrons. The impact lasts 10-15 s. The primary effect of radiation is realized in physical, physicochemical and chemical processes with the formation of chemically active free radicals (H, OH, HO2) with high oxidizing and reducing properties. Subsequently, various peroxide compounds are formed, inhibiting the activity of some enzymes and increasing others, which play an important role in the processes of autolysis (self-dissolution) of body tissues. The appearance in the blood of decay products of radiosensitive tissues and pathological metabolism when exposed to high doses of ionizing radiation is the basis for the formation of toxemia - poisoning of the body associated with the circulation of toxins in the blood. Of primary importance in the development of radiation injuries are disturbances in the physiological regeneration of cells and tissues, as well as changes in the functions of regulatory systems.

Radioactive contamination of the area

Its main sources are nuclear fission products and radioactive isotopes formed as a result of the acquisition of radioactive properties by the elements from which nuclear weapons are made and those that make up the soil. A radioactive cloud is formed from them. It rises to a height of many kilometers and is transported with air masses over considerable distances. Radioactive particles falling from the cloud to the ground form a zone of radioactive contamination (trace), the length of which can reach several hundred kilometers. Radioactive substances pose the greatest danger in the first hours after deposition, since their activity is highest during this period.

Electromagnetic pulse .

This is a short-term electromagnetic field that occurs during the explosion of a nuclear weapon as a result of the interaction of gamma radiation and neutrons emitted during a nuclear explosion with atoms of the environment. The consequence of its impact is burnout or breakdown of individual elements of radio-electronic and electrical equipment. People can only be harmed if they come into contact with wire lines at the time of the explosion.

A type of nuclear weapon is neutron and thermonuclear weapons.

Neutron weapons are small-sized thermonuclear ammunition with a power of up to 10 kt, designed primarily to destroy enemy personnel through the action of neutron radiation. Neutron weapons are classified as tactical nuclear weapons.

One day - one truth" url="https://diletant.media/one-day/26522782/">

7 countries possessing nuclear weapons form nuclear club. Each of these states spent millions to create their own atomic bomb. Development has been going on for years. But without the gifted physicists who were tasked with conducting research in this area, nothing would have happened. About these people in today's Diletant selection. media.

Robert Oppenheimer

The parents of the man under whose leadership the world's first atomic bomb was created had nothing to do with science. Oppenheimer's father was involved in the textile trade, his mother was an artist. Robert graduated from Harvard early, took a course in thermodynamics and became interested in experimental physics.


After several years of work in Europe, Oppenheimer moved to California, where he lectured for two decades. When the Germans discovered uranium fission in the late 1930s, the scientist began to think about the problem of nuclear weapons. Since 1939, he actively participated in the creation of the atomic bomb as part of the Manhattan Project and directed the laboratory at Los Alamos.

There, on July 16, 1945, Oppenheimer’s “brainchild” was tested for the first time. “I have become death, the destroyer of worlds,” said the physicist after the tests.

A few months later, atomic bombs were dropped on the Japanese cities of Hiroshima and Nagasaki. Oppenheimer has since insisted on the use of atomic energy exclusively for peaceful purposes. Having become a defendant in a criminal case due to his unreliability, the scientist was removed from secret developments. He died in 1967 from laryngeal cancer.

Igor Kurchatov

The USSR acquired its own atomic bomb four years later than the Americans. It could not have happened without the help of intelligence officers, but the merits of the scientists who worked in Moscow should not be underestimated. Atomic research was led by Igor Kurchatov. His childhood and youth were spent in Crimea, where he first learned to be a mechanic. Then he graduated from the Faculty of Physics and Mathematics of the Taurida University and continued to study in Petrograd. There he entered the laboratory famous Abram Ioffe.

Kurchatov headed the Soviet atomic project when he was only 40 years old. Years of painstaking work involving leading specialists have brought long-awaited results. Our country's first nuclear weapon, called RDS-1, was tested at the Semipalatinsk test site on August 29, 1949.

The experience accumulated by Kurchatov and his team allowed the Soviet Union to subsequently launch the world's first industrial nuclear power plant, as well as a nuclear reactor for a submarine and an icebreaker, which no one had achieved before.

Andrey Sakharov

The hydrogen bomb appeared first in the United States. But the American model was the size of a three-story house and weighed more than 50 tons. Meanwhile, the RDS-6s product, created by Andrei Sakharov, weighed only 7 tons and could fit on a bomber.

During the war, Sakharov, while evacuated, graduated with honors from Moscow State University. He worked as an engineer-inventor at a military plant, then entered graduate school at the Lebedev Physical Institute. Under the leadership of Igor Tamm, he worked in a research group for the development of thermonuclear weapons. Sakharov came up with the basic principle of Soviet hydrogen bomb- puff pastry

The first Soviet hydrogen bomb was tested in 1953

The first Soviet hydrogen bomb was tested near Semipalatinsk in 1953. To evaluate its destructive capabilities, a city of industrial and administrative buildings was built at the test site.

Since the late 1950s, Sakharov devoted a lot of time to human rights activities. He condemned the arms race, criticized the communist government, spoke out for the abolition of the death penalty and against forced psychiatric treatment of dissidents. Opposed the introduction Soviet troops to Afghanistan. Andrei Sakharov was awarded Nobel Prize peace, and in 1980 he was exiled to Gorky for his beliefs, where he repeatedly went on hunger strikes and from where he was able to return to Moscow only in 1986.

Bertrand Goldschmidt

The ideologist of the French nuclear program was Charles de Gaulle, and the creator of the first bomb was Bertrand Goldschmidt. Before the start of the war, the future specialist studied chemistry and physics and joined Marie Curie. The German occupation and the Vichy government's attitude towards Jews forced Goldschmidt to stop his studies and emigrate to the United States, where he collaborated first with American and then with Canadian colleagues.


In 1945, Goldschmidt became one of the founders of the French Atomic Energy Commission. The first test of the bomb created under his leadership occurred only 15 years later - in the southwest of Algeria.

Qian Sanqiang

China joined the club nuclear powers only in October 1964. Then the Chinese tested their own atomic bomb with a yield of more than 20 kilotons. Mao Zedong decided to develop this industry after his first trip to Soviet Union. In 1949, Stalin showed the great helmsman the capabilities of nuclear weapons.

The Chinese nuclear project was led by Qian Sanqiang. A graduate of the physics department of Tsinghua University, he went to study in France at public expense. He worked at the Radium Institute of the University of Paris. Qian communicated a lot with foreign scientists and carried out quite serious research, but he became homesick and returned to China, taking several grams of radium as a gift from Irene Curie.

The question of the creators of the first Soviet nuclear bomb is quite controversial and requires more detailed study, but about who really father of the Soviet atomic bomb, There are several entrenched opinions. Most physicists and historians believe that the main contribution to the creation of Soviet nuclear weapons was made by Igor Vasilyevich Kurchatov. However, some have expressed the opinion that without Yuli Borisovich Khariton, the founder of Arzamas-16 and the creator of the industrial basis for obtaining enriched fissile isotopes, the first test of this type of weapon in the Soviet Union would have dragged on for several more years.

Let us consider the historical sequence of research and development work to create a practical model of an atomic bomb, leaving aside theoretical studies of fissile materials and the conditions for the occurrence of a chain reaction, without which a nuclear explosion is impossible.

For the first time, a series of applications for obtaining copyright certificates for the invention (patents) of the atomic bomb was filed in 1940 by employees of the Kharkov Institute of Physics and Technology F. Lange, V. Spinel and V. Maslov. The authors examined issues and proposed solutions for the enrichment of uranium and its use as an explosive. The proposed bomb had a classic detonation scheme (cannon type), which was later, with some modifications, used to initiate a nuclear explosion in American uranium-based nuclear bombs.

The outbreak of the Great Patriotic War slowed down theoretical and experimental research in the field of nuclear physics, and the largest centers (Kharkov Institute of Physics and Technology and the Radium Institute - Leningrad) ceased their activities and were partially evacuated.

Beginning in September 1941, the intelligence agencies of the NKVD and the Main Intelligence Directorate of the Red Army began to receive an increasing amount of information about the special interest shown in British military circles in the creation explosives based on fissile isotopes. In May 1942, the Main Intelligence Directorate, having summarized the materials received, reported to the State Defense Committee (GKO) about the military purpose of the nuclear research being carried out.

Around the same time, technical lieutenant Georgy Nikolaevich Flerov, who in 1940 was one of the discoverers of the spontaneous fission of uranium nuclei, wrote a letter personally to I.V. Stalin. In his message, the future academician, one of the creators of Soviet nuclear weapons, draws attention to the fact that publications on work related to the fission of the atomic nucleus have disappeared from the scientific press of Germany, Great Britain and the United States. According to the scientist, this may indicate a reorientation of “pure” science into the practical military field.

In October - November 1942, the NKVD foreign intelligence reported to L.P. Beria provides all available information about work in the field of nuclear research, obtained by illegal intelligence officers in England and the USA, on the basis of which the People's Commissar writes a memo to the head of state.

At the end of September 1942, I.V. Stalin signs a resolution of the State Defense Committee on the resumption and intensification of “uranium work,” and in February 1943, after studying the materials presented by L.P. Beria, a decision is made to transfer all research on the creation of nuclear weapons (atomic bombs) into a “practical direction.” General management and coordination of all types of work were entrusted to the Deputy Chairman of the State Defense Committee V.M. Molotov, the scientific management of the project was entrusted to I.V. Kurchatov. Management of the search for deposits and extraction of uranium ore was entrusted to A.P. Zavenyagin, M.G. was responsible for the creation of enterprises for uranium enrichment and heavy water production. Pervukhin, and People's Commissar of Non-ferrous Metallurgy P.F. Lomako “trusted” to accumulate 0.5 tons of metallic (enriched to the required standards) uranium by 1944.

At this point, the first stage (the deadlines for which were missed), providing for the creation of an atomic bomb in the USSR, was completed.

After the United States dropped atomic bombs on Japanese cities, the Soviet leadership saw firsthand the lag scientific research and practical work on the creation of nuclear weapons from their competitors. To intensify and create an atomic bomb as quickly as possible short time On August 20, 1945, a special decree of the State Defense Committee was issued on the creation of Special Committee No. 1, whose functions included the organization and coordination of all types of work on the creation of a nuclear bomb. L.P. is appointed as the head of this emergency body with unlimited powers. Beria, scientific leadership is entrusted to I.V. Kurchatov. Direct management of all research, development and manufacturing enterprises should have been carried out by People's Commissar of Armaments B.L. Vannikov.

Due to the fact that scientific, theoretical and experimental research has been completed, intelligence data about the organization industrial production uranium and plutonium were obtained, intelligence officers obtained schematics for American atomic bombs, the greatest difficulty was the transfer of all types of work to an industrial basis. To create enterprises for the production of plutonium, the city of Chelyabinsk-40 was built from scratch (scientific director I.V. Kurchatov). In the village of Sarov (future Arzamas - 16) a plant was built for the assembly and production on an industrial scale of the atomic bombs themselves (scientific director - chief designer Yu.B. Khariton).

Thanks to the optimization of all types of work and strict control over them by L.P. Beria, who, however, did not interfere creative development ideas included in the projects, in July 1946, technical specifications were developed for the creation of the first two Soviet atomic bombs:

• "RDS - 1" - a bomb with a plutonium charge, the detonation of which was carried out using the implosion type;
• "RDS - 2" - a bomb with a cannon detonation of a uranium charge.

I.V. was appointed scientific director of the work on the creation of both types of nuclear weapons. Kurchatov.

Paternity rights

Tests of the first atomic bomb created in the USSR, “RDS-1” (the abbreviation in various sources stands for “jet engine C” or “Russia makes it itself”) took place in late August 1949 in Semipalatinsk under the direct leadership of Yu.B. Khariton. The power of the nuclear charge was 22 kilotons. However, from the point of view of modern copyright law, it is impossible to attribute the paternity of this product to any of the Russian (Soviet) citizens. Earlier, when developing the first practical model suitable for military use, the USSR Government and the leadership of Special Project No. 1 decided to copy as much as possible a domestic implosion bomb with a plutonium charge from the American “Fat Man” prototype dropped on the Japanese city of Nagasaki. Thus, the “fatherhood” of the first nuclear bomb of the USSR most likely belongs to General Leslie Groves, the military leader of the Manhattan Project, and Robert Oppenheimer, known throughout the world as the “father of the atomic bomb” and who provided scientific leadership over the project "Manhattan". The main difference between the Soviet model and the American one is the use of domestic electronics in the detonation system and a change in the aerodynamic shape of the bomb body.

The RDS-2 product can be considered the first “purely” Soviet atomic bomb. Despite the fact that it was initially planned to copy the American uranium prototype “Baby”, the Soviet uranium atomic bomb “RDS-2” was created in an implosion version, which had no analogues at that time. L.P. participated in its creation. Beria – general project management, I.V. Kurchatov – scientific supervisor of all types of work and Yu.B. Khariton is the scientific director and chief designer responsible for the production of a practical bomb sample and its testing.

When talking about who is the father of the first Soviet atomic bomb, one cannot lose sight of the fact that both RDS-1 and RDS-2 were exploded at the test site. The first atomic bomb dropped from a Tu-4 bomber was the RDS-3 product. Its design was similar to the RDS-2 implosion bomb, but had a combined uranium-plutonium charge, which made it possible to increase its power, with the same dimensions, to 40 kilotons. Therefore, in many publications, Academician Igor Kurchatov is considered the “scientific” father of the first atomic bomb actually dropped from an airplane, since his scientific colleague, Yuli Khariton, was categorically against making any changes. “Paternity” is also supported by the fact that throughout the history of the USSR L.P. Beria and I.V. Kurchatov were the only ones who in 1949 were awarded the title of Honorary Citizen of the USSR - “... for the implementation of the Soviet atomic project, the creation of the atomic bomb.”