Поиск :
Личный кабинет :
Электронный каталог: Popov, E. P. - Analyzing Point Defect Polarization in Tungsten and Tungsten Carbide Under High Gamma Irradiation...
Popov, E. P. - Analyzing Point Defect Polarization in Tungsten and Tungsten Carbide Under High Gamma Irradiation...
Статья
Автор: Popov, E. P.
International Journal of Refractory Metals and Hard Materials [Electronic resource]: Analyzing Point Defect Polarization in Tungsten and Tungsten Carbide Under High Gamma Irradiation...
б.г.
ISBN отсутствует
Автор: Popov, E. P.
International Journal of Refractory Metals and Hard Materials [Electronic resource]: Analyzing Point Defect Polarization in Tungsten and Tungsten Carbide Under High Gamma Irradiation...
б.г.
ISBN отсутствует
Статья
Popov, E.P.
Analyzing Point Defect Polarization in Tungsten and Tungsten Carbide Under High Gamma Irradiation for Radiation Shielding Applications / E.P.Popov, A.A.Donkov, N.V.M.Trung, S.F.Samadov, A.A.Sidorin, O.S.Orlov, M.N.Mirzayev, [et al.] // International Journal of Refractory Metals and Hard Materials [Electronic resource]. – 2024. – Vol. 124. – P. 106850. – URL: https://doi.org/10.1016/j.ijrmhm.2024.106850. – Bibliogr.: 45.
In this study, polycrystalline tungsten and tungsten carbide samples were irradiated with gamma rays at energies of 1.17 MeV and 1.33 MeV, respectively. The irradiation was performed using an “MRX-*g-25 M” radiation camera with an activity of approximately 6.54 Gy/s. Doppler positron spectroscopy (DPS) and positron lifetime spectroscopy (PALS) were utilized to investigate the mechanisms of defect formation in the polycrystalline structure of tungsten samples at different doses of gamma irradiation. In the initial tungsten sample, a significant number of free monovacancy (1 V) clusters were present. An increase in the positron lifetime component τ&sub(1) was observed with increasing gamma irradiation, accompanied by a decrease in its intensity. The τ&sub(2) value (218 *( 2 ps) suggests the presence of divacancies with a considerable intensity (∼20%). As the gamma dose accumulated, a dynamic evolution of structural defects was evident. The tungsten carbide (WC) samples displayed greater plasticity in response to increasing gamma irradiation doses. Changes in the void volume ratio within the samples were recorded as the gamma dose increased, and movement of these voids towards the surface was observed. Additionally, the operational limits of gamma-irradiated tungsten were assessed, determining a functional threshold of up to 3.378 MGy. This study provides valuable insights into the defect dynamics and structural changes in tungsten and tungsten carbide under gamma irradiation, contributing to the understanding of their behavior in radiation environments.
Спец.(статьи,препринты) = С 349.1 - Действие излучения на материалы$
ОИЯИ = ОИЯИ (JINR)2024
Бюллетени = 48/024
Popov, E.P.
Analyzing Point Defect Polarization in Tungsten and Tungsten Carbide Under High Gamma Irradiation for Radiation Shielding Applications / E.P.Popov, A.A.Donkov, N.V.M.Trung, S.F.Samadov, A.A.Sidorin, O.S.Orlov, M.N.Mirzayev, [et al.] // International Journal of Refractory Metals and Hard Materials [Electronic resource]. – 2024. – Vol. 124. – P. 106850. – URL: https://doi.org/10.1016/j.ijrmhm.2024.106850. – Bibliogr.: 45.
In this study, polycrystalline tungsten and tungsten carbide samples were irradiated with gamma rays at energies of 1.17 MeV and 1.33 MeV, respectively. The irradiation was performed using an “MRX-*g-25 M” radiation camera with an activity of approximately 6.54 Gy/s. Doppler positron spectroscopy (DPS) and positron lifetime spectroscopy (PALS) were utilized to investigate the mechanisms of defect formation in the polycrystalline structure of tungsten samples at different doses of gamma irradiation. In the initial tungsten sample, a significant number of free monovacancy (1 V) clusters were present. An increase in the positron lifetime component τ&sub(1) was observed with increasing gamma irradiation, accompanied by a decrease in its intensity. The τ&sub(2) value (218 *( 2 ps) suggests the presence of divacancies with a considerable intensity (∼20%). As the gamma dose accumulated, a dynamic evolution of structural defects was evident. The tungsten carbide (WC) samples displayed greater plasticity in response to increasing gamma irradiation doses. Changes in the void volume ratio within the samples were recorded as the gamma dose increased, and movement of these voids towards the surface was observed. Additionally, the operational limits of gamma-irradiated tungsten were assessed, determining a functional threshold of up to 3.378 MGy. This study provides valuable insights into the defect dynamics and structural changes in tungsten and tungsten carbide under gamma irradiation, contributing to the understanding of their behavior in radiation environments.
Спец.(статьи,препринты) = С 349.1 - Действие излучения на материалы$
ОИЯИ = ОИЯИ (JINR)2024
Бюллетени = 48/024