V. D. Borzosekov, N. S. Akhmadullina, A. S. Sokolov, T. E. Gayanova, A. D. Rezaeva, V. D. Stepakhin, E. M. Konchekov, D. V. Malakhov, E. V. Voronova, I. R. Nugaev, V. P. Logvinenko, A. V. Knyazev, A. A. Letunov, D. E. Kharlachev, E. A. Obraztsova, T. I. Morozova, M. A. Zaitsev, A. V. Ishchenko, I. A. Weinstein, V. I. Grohovsky, O. N. Shishilov, N. N. Skvortsova
{"title":"利用微波放电从陨石物质、其类似物和月球碎屑模拟物中获取等离子尘云","authors":"V. D. Borzosekov, N. S. Akhmadullina, A. S. Sokolov, T. E. Gayanova, A. D. Rezaeva, V. D. Stepakhin, E. M. Konchekov, D. V. Malakhov, E. V. Voronova, I. R. Nugaev, V. P. Logvinenko, A. V. Knyazev, A. A. Letunov, D. E. Kharlachev, E. A. Obraztsova, T. I. Morozova, M. A. Zaitsev, A. V. Ishchenko, I. A. Weinstein, V. I. Grohovsky, O. N. Shishilov, N. N. Skvortsova","doi":"10.1134/S0038094624700138","DOIUrl":null,"url":null,"abstract":"<p>In the experiment, plasma–dust clouds were obtained from the substance of the Tsarev meteorite, a simulant of lunar regolith LMS-1D and ilmenite concentrate using a microwave discharge in powder media. For each of the samples, the dynamics of the development of the discharge and the formation of a plasma–dust cloud with subsequent relaxation after the end of the microwave pulse were recorded. From the emission spectra of the plasma and the surface of a solid body, the temperatures of the gas, electrons and surface were determined. A comparison of the phase and elemental composition of the initial samples and samples after exposure to plasma showed that there is no significant change in the composition. However, scanning electron microscopy results clearly indicate spheroidization of the original angular and irregularly shaped particles. The appearance of spherical particles is also observed, the dimensions of which are larger than the linear dimensions of the particles in the original sample. The results obtained indicate the possibility of using such experiments to study chemical and plasma-chemical processes of synthesis and modification of substances under conditions of plasma–dust clouds encountered in space phenomena.</p>","PeriodicalId":778,"journal":{"name":"Solar System Research","volume":"58 3","pages":"289 - 314"},"PeriodicalIF":0.6000,"publicationDate":"2024-05-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://link.springer.com/content/pdf/10.1134/S0038094624700138.pdf","citationCount":"0","resultStr":"{\"title\":\"Obtaining Plasma–Dust Clouds from Meteoritic Matter, its Analogs and Simulants of Lunar Regolith Using Microwave Discharge\",\"authors\":\"V. D. Borzosekov, N. S. Akhmadullina, A. S. Sokolov, T. E. Gayanova, A. D. Rezaeva, V. D. Stepakhin, E. M. Konchekov, D. V. Malakhov, E. V. Voronova, I. R. Nugaev, V. P. Logvinenko, A. V. Knyazev, A. A. Letunov, D. E. Kharlachev, E. A. Obraztsova, T. I. 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Obtaining Plasma–Dust Clouds from Meteoritic Matter, its Analogs and Simulants of Lunar Regolith Using Microwave Discharge
In the experiment, plasma–dust clouds were obtained from the substance of the Tsarev meteorite, a simulant of lunar regolith LMS-1D and ilmenite concentrate using a microwave discharge in powder media. For each of the samples, the dynamics of the development of the discharge and the formation of a plasma–dust cloud with subsequent relaxation after the end of the microwave pulse were recorded. From the emission spectra of the plasma and the surface of a solid body, the temperatures of the gas, electrons and surface were determined. A comparison of the phase and elemental composition of the initial samples and samples after exposure to plasma showed that there is no significant change in the composition. However, scanning electron microscopy results clearly indicate spheroidization of the original angular and irregularly shaped particles. The appearance of spherical particles is also observed, the dimensions of which are larger than the linear dimensions of the particles in the original sample. The results obtained indicate the possibility of using such experiments to study chemical and plasma-chemical processes of synthesis and modification of substances under conditions of plasma–dust clouds encountered in space phenomena.
期刊介绍:
Solar System Research publishes articles concerning the bodies of the Solar System, i.e., planets and their satellites, asteroids, comets, meteoric substances, and cosmic dust. The articles consider physics, dynamics and composition of these bodies, and techniques of their exploration. The journal addresses the problems of comparative planetology, physics of the planetary atmospheres and interiors, cosmochemistry, as well as planetary plasma environment and heliosphere, specifically those related to solar-planetary interactions. Attention is paid to studies of exoplanets and complex problems of the origin and evolution of planetary systems including the solar system, based on the results of astronomical observations, laboratory studies of meteorites, relevant theoretical approaches and mathematical modeling. Alongside with the original results of experimental and theoretical studies, the journal publishes scientific reviews in the field of planetary exploration, and notes on observational results.
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