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Екатерина Вавилова – All sciences. №2, 2023. International Scientific Journal (страница 2)

18

As a result, it would take 15 hours 40 minutes and 30.27 seconds for one printer to create this hall, but since 2 such devices worked, the building was completed in 7 hours 50 minutes and 15.13 seconds.

So far the work has progressed at such a pace that the first model was ready at 5 o'clock in the morning, the second at 8 o'clock in the morning, then the large model was completed at 12 o'clock in the afternoon, and all the small buildings were already built at 10 o'clock in the afternoon, since 2 printers were working together . Then they began to create a conference room and by six o'clock in the evening they had completed. By that time, three large buildings had already been built and more were under construction. Then, by 3 pm, the second “cube” was ready, which started work when the first one completed 3 buildings, as already mentioned, and together with it by 5 pm they completed all 6 large buildings for cyclotrons.

Now there were 6 more of the same buildings for energy generation, and then there were small works. Furnishing, repair, decoration of the previous buildings were in full swing. In a record 2 hours, the third large printer was already ready, which, together with the existing two, was able to complete the remaining 6 buildings in 2 hours. Therefore, by 7 pm, the entire building with 18 blocks and halls was completely ready, and only work on decorating the inside continued.

The roofs were also already covered, and thanks to the creation of only 5 printers instead of 18, the count was able to save a little less than half of the originally named budget, for the construction of all equipment and buildings, respectively. Finally, the case was completed with a huge gain of 11 hours from the named time. They wanted to finish the construction at 6 am on May 11, but it turned out that they had already finished at 7 pm on May 10, it was a victory!

And just a titanic work was done, epoch-making!

The purpose of this description was to convey the basic idea that everything is possible, even such an amazing task as building an entire power plant in less than 2 days, albeit with the involvement of a huge amount of a wide variety of resources, as well as using the latest 3D building printing technology, with a stop at the stage of completing the printing of the first floor and the installation of the structure, on top of which the printing of the next floor will continue in parallel.

References

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2. Bayer V. E. Architectural materials science; Architecture-S – Moscow, 2006. – 264 p.

3. Belokonev E. N., Abukhanov A. Z., Belokoneva T. M., Chistyakov A. A. Fundamentals of architecture of buildings and structures; Phoenix – Moscow, 2009. – 336 p.

4. Boitemirov F. A., Golovina V. M., Ulitskaya E. M. Calculation of structures made of wood and plastic; Academy – Moscow, 2007. – 160 p.

5. Giyasov Adkham Planar and spatial structures of building coverings; Publishing House of the Association of Construction Universities – Moscow, 2008. – 144 p.

6. Grebennik R. A., Grebennik V. R. Installation of steel and reinforced concrete building structures; Academy – Moscow, 2009. – 288 p.

7. I. V. Grigoriev, V. I. Prokop’ev, and Yu. V. Tverdy, Deformation, Stability, and Vibrations of Shell Structures; Publishing House of the Association of Construction Universities – Moscow, 2007. – 208 p.

8. Devyataeva GV Technology of reconstruction and modernization of buildings. Tutorial; Infra-M -, 2003. – 256 p.

9. Iodo I. A., Potaev G. A. Urban planning and territorial planning; Phoenix – Moscow, 2008. – 288 p.

10. Kashkina L. V. Fundamentals of urban planning; Vlados – Moscow, 2005. – 248 p.

11. Mailyan L. R., Lazarev A. G., Seferov G. G., Batienkov V. T. Structures of buildings and structures with static elements; Infra-M -, 2010. – 688 p.

12. Mailyan R. L., Mailyan D. R., Veselev Yu. A. Building structures; Phoenix – Moscow, 2010. – 880 p.

13. Maklakova T. G. Architectural and constructive design of buildings. Volume 1. Residential buildings; Architecture-S – Moscow, 2010. – 328 p.

14. Mironov V. V., Mironov D. V., Chikishev V. M., Shapoval A. F. Use of soft geosynthetic shell structures in construction; Publishing House of the Association of Construction Universities – Moscow, 2005. – 573 p.

15. Mityugov E. A. Course of metal structures; Publishing House of the Association of Construction Universities – Moscow, 2008. – 120 p.

16. Nikulin A. D., Shmitko E. I., Zuev B. M. Design of enterprises of building materials, products and structures; Prospect Nauki – Moscow, 2006. – 352 p.

17. Ponamarev A. B. Reconstruction of the underground space; Publishing House of the Association of Construction Universities – Moscow, 2006. – 232 p.

USING PHOTON TUNNELING TECHNOLOGY FOR DIRECT TELEPORTATION

Aliev Ibratjon Khatamovich

2nd year student of the Faculty of Mathematics and Informatics, Fergana State University

Fergana State University, Fergana, Uzbekistan

Аннотация. В работе описан метод, являющийся аналогом квантовой телепортации при перемещении определённых объектов с указанием некоторых парадоксом. При этом большое внимание уделяется общему представлению процесса, а также приводятся математические закономерности. Данный метод также является своего рода решением вопроса этической проблемы классической квантовой телепортации.

Ключевые слова: фотонное туннелирование, телепортация, переход, ядерные реакции, запутанные частицы.

Annotation. The paper describes a method that is analogous to quantum teleportation when moving certain objects with the indication of some paradoxes. At the same time, much attention is paid to the general representation of the process, and mathematical patterns are also given. This method is also a kind of solution to the ethical problem of classical quantum teleportation.

Keywords: photon tunneling, teleportation, transition, nuclear reactions, entangled particles.

Today, the phenomenon of quantum teleportation is actively known, which makes it possible to entangle two certain particles, linking their spins to each other, while most often two photons or electrons can be connected. To bind photons, the most commonly used is the passage of a laser beam (with more uniform characteristics) and, if necessary, which is more likely to interfere through a nonlinear crystal with separation into two additional beams. The most common are barium beta-borate, lithium triborate, potassium titanyl phosphate, potassium niobate, or the more commonly used L-arginine maleine dihydrate or 2-L-methionyl maleine dihydrate.

Two electrons can also be entangled in a similar way, but the problem was that upon contact of such particles with others with a subsequent change in their spin, the second entangled particle, located at an arbitrarily large distance, turned into an exact copy of the given particle, when it collapsed fully. But here the question initially arises of delivering the second particle – a photon or electron to the place where the object itself needs to be sent, and this in itself causes both inconvenience and too much time wasting to move at least to other exoplanets located at a distance no less than tens of light years.

Moreover, the very assertion of the destruction of the original object leads to a kind of strange feeling about the ethics of this kind of experiment, since when using macro objects or biological organisms, the original being is simply destroyed and its copy remains. A companion, rather than a substitute for such an idea, is a new theory of photon tunneling based on the following idea.

Any part in any system has a precise defined energy that can be transferred in the form of a wave, in particular in the form of a photon or gamma ray, and also in the form of a particle with high energy. For this example, deuterons will be used, into which all particles of the body will be generated according to (1), when bombarded by a stream of electrons with certain energies.

But it is worth considering that in this case, the electron energy was selected resonantly, that is, in such a way as to increase the probability of a given reaction channel in relation to others up to 96—97%, as happens in energy resonant nuclear reactions with increased monochromaticity. And since there are no more than 1-5 particles with almost identical energy in the body, then in 4.85 cases out of 5 particles, they will be converted into such deuteron-neutron pairs correctly, and the remaining parts can be turned into the most probabilistic channel, forming other more massive particles, most often nuclei, by the energies of which it is easy to understand which of the pairs they belong to.

Further, due to their charge, deuterons are removed from the chamber, and neutrons, with residual nuclei, are additionally irradiated by protons, while equation (2) applies for nuclei, and (3) for neutrons.

The energy of proton beams is also selected resonantly. And all electron shells for all irradiated nuclei under the influence of an electric field with an accurate calculation of energy changes when they meet with a parasitic electric field of electromagnets (when rotated by magnetic fields) are calculated separately. Further, the neutrons remaining after this are additionally bombarded by protons according to (3). As a result, the body is divided into 3 layers of deuteron flows with their own pairs and identical energies, each of which is selected and calculated separately. Thus, there are three groups of particles – deuterons and electrons, into which the organism has turned, and electrons, according to the energy of which it is possible to write down the energy in the form of information for each deuteron-electron particle of the organism.