On the Possibility of Initialization of Synthesis in Small-sized Installations with Quadrupole Magnetic Systems with Spherical Сumulation of Shock Magnetic Waves in the Blanket Configuration of Plasma Discrets
- 作者: Somov A.I.1, Svirkov V.B.2, Radenko V.V.3, Dolgopolov M.V.1,4, Vasiliev I.V.1, Bagrov A.R.1
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隶属关系:
- Samara National Research University named after academician S.P. Korolev
- LLC Technological Platform “Nuclear and Subatomic Technologies” (TP A&ST)
- LLC Scientific and Production Company “New Energy”
- Samara State Technical University
- 期: 卷 10, 编号 2 (2023)
- 页面: 70-88
- 栏目: NANOTECHNOLOGY AND NANOMATERIALS
- URL: https://journals.eco-vector.com/2313-223X/article/view/568079
- DOI: https://doi.org/10.33693/2313-223X-2023-10-2-70-88
- EDN: https://elibrary.ru/CLYCZR
- ID: 568079
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详细
The article presents an overview of models for solving the problem of controlled nuclear fusion, including in small-sized installations, methods and technology for obtaining and forming electronically controlled plasma and ion flows in a magnetic field. The sizes of such an installation in the pilot version are up to 1.5 meters long, due to the grouping of flows by sampling with a frequency of about 1 kHz achievable for materials today, multi-passability in the synthesis chamber, in traps and setting the laws of following with feedback for ion flows in plasma layers in magnetic field systems with the large gradient. The shock wave causes rapid heating of the convection mixing region, triggering a process of constant energy exchange between the heated mixture 11B–9Be and the lithium shell and, passing through the layer 11B–9Be, reaches the geometric center of the magnetic trap, where a small spherical cavity will be maintained, necessary for unlimited spherical cumulation on the cavity. This leads to a rapid increase in temperature and pressure in the area of collapse of the bubble, and makes it possible to increase the temperature to 108 K, which allows the launch of fusion reactions.
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作者简介
Artem Somov
Samara National Research University named after academician S.P. Korolev
编辑信件的主要联系方式.
Email: artem.somov.2002@mail.ru
ORCID iD: 0009-0007-4466-537X
student at the Samara National Research University named after academician S.P. Korolev
俄罗斯联邦, SamaraVasily Svirkov
LLC Technological Platform “Nuclear and Subatomic Technologies” (TP A&ST)
Email: tp-aist@mail.ru
ORCID iD: 0009-0003-3061-4476
SPIN 代码: 2106-5461
chief engineer of LLC Technological Platform “Nuclear and Subatomic Technologies” (TP A&ST)
俄罗斯联邦, SamaraVitaly Radenko
LLC Scientific and Production Company “New Energy”
Email: quasar_ltd@mail.ru
ORCID iD: 0009-0008-3353-2667
SPIN 代码: 2499-4250
chief designer of the LLC Scientific and Production Company “New Energy”
俄罗斯联邦, SamaraMikhail Dolgopolov
Samara National Research University named after academician S.P. Korolev; Samara State Technical University
Email: mikhaildolgopolov68@gmail.com
ORCID iD: 0000-0002-8725-7831
SPIN 代码: 2104-1911
Candidate of Physical and Mathematical Sciences, Associate Professor; associate professor at the Department of All and Theoretical Physic, Head of the joint Research Laboratory of Mathematical Physics of the Samara National Research University named after Academician S.P. Korolev; associate professor at the Department of Higher Mathematics of the Samara State Technical University
俄罗斯联邦, Samara; SamaraIlya Vasiliev
Samara National Research University named after academician S.P. Korolev
Email: sinisterevil163@gmail.com
ORCID iD: 0009-0006-8688-897X
student at the Samara National Research University named after academician S.P. Korolev
俄罗斯联邦, SamaraAlexander Bagrov
Samara National Research University named after academician S.P. Korolev
Email: alexander.bagrov00@mail.ru
ORCID iD: 0000-0002-1098-0300
SPIN 代码: 1382-3827
student at the Samara National Research University named after academician S.P. Korolev
俄罗斯联邦, Samara参考
- Miyamoto K. Plasma physics for controlled fusion. Springer Series on Atomic, Optical, and Plasma Physics (SSAOPP) 2016. Vol. 92. 495 p.
- The physics and technology of ion sources. 2nd publ., rev. and ext. ed. I.G. Brown (ed.). Wiley-VCH, 2004. 396p.
- Mesyats G.A. Pulsed power. Springer Science + Business Media, Inc. 570 p.
- Forrester A.T. Large ion beams, fundamentals of generation and propagation. 1988. Wiley-VCH. 325 p.
- Morozov A.I. Introduction to plasma dynamics. CRC Press, 2013. 834 p.
- Ryutov D.D. Open-ended traps. Sov. Phys. Usp. 1988. No. 31. Pp. 300–327. (In Rus.)
- Umarov G.Ya., Suyarov N., Baklitsky B.E. Study of rotating plasma. Dokl. Academy of Sciences of the Uzbek SSR. 1967. No. 12. Pp. 19-21. (In Rus.)
- Umarov G.Ya., Alimov A.K., Baklitsky B.E. Plasma torch with rotating flame ring. Reports of the Academy of Sciences of the Uzbek SSR. 1967. No. 9. Pp. 60-62. (In Rus.)
- Bayborodov Yu.T., Ioffe M.S., Kanaev B.I. et al. Plasma physics and controlled nuclear fusion research. Conference Proceedings, Madison, 1971. IAEA. 1971. Vol. 2. P. 721.
- Coensgen F.H., Cummins W.F., Logan. B.G. et al. Stabilization of a neutral-beam-sustained, mirror-confined plasma. Phys. Rev. Lett. 1975. Vol. 35. Pp. 1501–1503.
- Ryzhkov S.V., Chirkov A.Yu. Alternative fusion fuels and systems. CRC Press, 2020. 210 p.
- Ryzhkov S.V. A field-reversed magnetic configuration and applications of high-temperature FRC plasma. Plasma Physics Reports. 2011. Vol. 37. No. 13. Pp. 1075–1081. (In Rus.)
- Dolgopolov M.V., Radenko V.V., Zanin G.G. et al. Electroni-cally controlled plasma power devices for sustainable and environmentally friendly electric energy technologies. Advances in Engineering Research. 2022. Issue 210. Pp. 197–205.
- Radenko A.V., Radenko V.V., Dolgopolov M.V. Modelling of magnetodynamic plasma flows. In: Nonequilibrium phase transformations: Materials science of III International Scientific Conference. 2017. No. 1 (1). Pp. 107–108. (In Rus.)
- Dolgopolov M.V., Zanin G.G., Ovchinnikov D.E. et al. Electronically controlled plasma electric generator. Patent for invention 2757666 C1, 10/20/2021. Application No. 2021105186 dated 01.03.2021. Byul. No. 29. 20.10.2021.
- Callaghan E.E., Maslen S.H. The magnetic field of a finite solenoid. NASA Technical Note. 1960.
- Martín-Luna P., Gimeno B., González-Iglesias D. et. al. On the magnetic field of a finite solenoid. IEEE Transactions on Magnetics. 2023. Vol. 59. Issue 4.
- Dolgopolov M.V., Zanin G.G., Radenko A.V. et al. Mathematical modeling of an ion multiphase flow in a plasma electric synthesis generator. Mathematical modeling and boundary value problems. In: Materials of the XI All-Russian Scientific Conference with international participation. In 2 vols. Vol. 1. Samara: Samara State Technical University, 2019. Pp. 258–263.
- Akimchenko A., Chepurnov V., Dolgopolov M. et al. Betavoltaic device in por-SiC/Si C-nuclear energy converter. EPJ Web of Conferences. 2017. Vol. 158. Vol. 158.
- Bezrodny Yu.G., Bomko V.A. Dynamics of particles in a linear accelerator of multicharged ions: Review according to dan. edema. and abroad. seals. State Committee for Use. Atom. Energy of the USSR, Central Research Institute Inform. and Tech.-econ. Research by Atom. Science and Technology. 1988.
- Grigoriev Yu.V., Novikov-Borodin A.V. Activated nuclear reactions in lithium- or boron-beryllium mixtures and hybrid energy systems based on them. INR RAS preprint 1425/2016.
- Yankov V.V. Attractors and frozen-in invariants in turbulent plasma. Phys. Usp. 1997. No. 40. Pp. 477–493. (In Rus.)
- Chukbar K.V. Lectures on transfer phenomena in plasma. Dolgoprudny: Intellect Publishing House, 2008.
- Space technology. G. Seifert (ed.). Moscow: Nauka, 1964. 728 p.
- Zababakhin E.I., Zababakhin I.E. Phenomena of unlimited cumulation. Moscow: Nauka, 1988. 342 p.
- Khalitova T.F. Deformation of shock waves in a bubble under its strong compression. Bulletin of the Nizhny Novgorod University named after N.I. Lobachevsky. 2011. No. 4-5. Pp. 2561–2563. (In Rus.)
- Bichenkov E.I. Two alternatives to magnetic cumulation are applied mechanics and technical physics. Lavrentiev Institute of Hydrodynamics SB RAS. 2000. Vol. 41. No. 5. (In Rus.)