Effect of electron beam energy on charging characteristics of polymer composites with the inclusion of carbon nanotubes
Vorobyeva E.A.
1,2, Evseev A.P.
1,3, Tatarintsev A. A.
3, Peshnina D.O.
1, Shemukhin A. A.
1,31Lomonosov Moscow State University, Skobeltsyn Institute of Nuclear Physics, Moscow, Russia
2National Research Center “Kurchatov Institute”, Moscow, Russia
3Moscow State University, Moscow, Russia
Email: vorkate89@mail.ru, ap.evseev@physics.msu.ru, tatarintsev@physics.msu.ru, shemuhin@gmail.com
The possibility of using polymer composite materials based on epoxy resins with the inclusion of carbon nanotubes as coatings with a low coefficient of secondary electron emission has been studied. Four types of samples were obtained: epoxy polymer, polymer composites with fillers (non-aligned and aligned carbon nanotubes, carbon soot). It is shown that the secondary electron emission yield depends on the structure of the introduced carbon filler, and polymer composites with aligned nanotubes exhibit antidynatron properties. Keywords: multi-walled carbon nanotubes, nanocomposites, electron beam, secondary electron emission. DOI: 10.61011/TPL.2023.06.56385.19556
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