Study of using pulsed beams to increase the radiation resistance of nitride ceramics to helium swelling

“…By analyzing the obtained data on reduction of helium-swelling value and comparing them with the literature data [15][16][17]19,20] on other methods of modification and protection against helium embrittlement, the following conclusions can be drawn. As is known from References [15][16][17], one method of increasing swelling resistance and subsequent structure degradation is the method of high-precision pulsed irradiation with electrons and ions.…”

“…This hypothesis is based on the assumption that dislocation defects isolated from each other due to small fluences of irradiation with heavy ions will create additional obstacles to migrating helium ions, thereby preventing them from agglomeration into large gas-filled bubbles. The basis for this hypothesis was a number of experimental works [14][15][16][17][18][19][20] aimed at studying the applicability of ionizing radiation to increase the radiation resistance of materials, as well as studying the mechanisms of radiation hardening of the near-surface layer of ceramics, steels, and multilayer coatings. Therefore, for example, in a number of works, the effect of radiation hardening at irradiation with high-precision pulse beams of near-surface layers of refractory materials and ceramics is considered [14][15][16][17][18][19][20][21][22].…”

“…The basis for this hypothesis was a number of experimental works [14][15][16][17][18][19][20] aimed at studying the applicability of ionizing radiation to increase the radiation resistance of materials, as well as studying the mechanisms of radiation hardening of the near-surface layer of ceramics, steels, and multilayer coatings. Therefore, for example, in a number of works, the effect of radiation hardening at irradiation with high-precision pulse beams of near-surface layers of refractory materials and ceramics is considered [14][15][16][17][18][19][20][21][22]. The authors of these works call the main hardening mechanism changes in dislocation density and amorphization processes, followed by the formation of amorphous inclusions in the structure of the near-surface radiation-modified layer.…”

“…Thus, by analyzing the literature data of previously carried out experimental works [14][15][16][17][18][19][20][21][22][23][24][25], one can make an assumption about the possible positive effect of radiation hardening of the near-surface layers of irradiated materials that consists in changing the dislocation density and defect structure of the layer. These changes can play both a positive effect, initiating changes that contribute to an increase in degradation resistance of materials, and a negative effect, consisting in the creation of active defect regions, near which subsequent radiation-induced defects will agglomerate.…”

Study of the Application Efficiency of Irradiation with Heavy Ions to Increase the Helium Swelling Resistance of BeO Ceramics

“…By analyzing the obtained data on reduction of helium-swelling value and comparing them with the literature data [15][16][17]19,20] on other methods of modification and protection against helium embrittlement, the following conclusions can be drawn. As is known from References [15][16][17], one method of increasing swelling resistance and subsequent structure degradation is the method of high-precision pulsed irradiation with electrons and ions.…”

“…This hypothesis is based on the assumption that dislocation defects isolated from each other due to small fluences of irradiation with heavy ions will create additional obstacles to migrating helium ions, thereby preventing them from agglomeration into large gas-filled bubbles. The basis for this hypothesis was a number of experimental works [14][15][16][17][18][19][20] aimed at studying the applicability of ionizing radiation to increase the radiation resistance of materials, as well as studying the mechanisms of radiation hardening of the near-surface layer of ceramics, steels, and multilayer coatings. Therefore, for example, in a number of works, the effect of radiation hardening at irradiation with high-precision pulse beams of near-surface layers of refractory materials and ceramics is considered [14][15][16][17][18][19][20][21][22].…”

“…The basis for this hypothesis was a number of experimental works [14][15][16][17][18][19][20] aimed at studying the applicability of ionizing radiation to increase the radiation resistance of materials, as well as studying the mechanisms of radiation hardening of the near-surface layer of ceramics, steels, and multilayer coatings. Therefore, for example, in a number of works, the effect of radiation hardening at irradiation with high-precision pulse beams of near-surface layers of refractory materials and ceramics is considered [14][15][16][17][18][19][20][21][22]. The authors of these works call the main hardening mechanism changes in dislocation density and amorphization processes, followed by the formation of amorphous inclusions in the structure of the near-surface radiation-modified layer.…”

“…Thus, by analyzing the literature data of previously carried out experimental works [14][15][16][17][18][19][20][21][22][23][24][25], one can make an assumption about the possible positive effect of radiation hardening of the near-surface layers of irradiated materials that consists in changing the dislocation density and defect structure of the layer. These changes can play both a positive effect, initiating changes that contribute to an increase in degradation resistance of materials, and a negative effect, consisting in the creation of active defect regions, near which subsequent radiation-induced defects will agglomerate.…”

Study of the Application Efficiency of Irradiation with Heavy Ions to Increase the Helium Swelling Resistance of BeO Ceramics

“…One of the most promising applications of thin-film coatings is their use as local protection of the most important components of microelectronic devices from the destabilizing effect of ionizing radiation [1][2][3][4][5]. The main principle of applying local protection is the use of thin films of complex phase composition and crystal structure to reduce the energy of incident particles due to the difference in energy losses in the crystal structure of coatings of different phase composition [6,7].…”

Study of the strength characteristics and radiation resistance of thin-film coatings based on CuX (X=Bi, Mg, Ni)

Recent Progress on Interfaces in Nanomaterials for Nuclear Radiation Resistance