Вплив гамма-опромінення на фізичні властивості прогонових розплаву сплавів Ti30Zr45Ni25
Ключові слова:
поглинання водню, аморфні сплави, фази Лавеса, опромінення
Анотація
Гамма-опромінення зразків швидко загартованого сплаву Ti30Zr45Ni25 до дози 104 рад не призводить до суттєвих змін їх фізичних властивостей (мікротвердості і питомого електричного опору), що узгоджується з високим ступенем безладу в вихідної мікроструктурі, яка не зазнає суттєвих змін при опроміненні. Представлені результати показують, що ці матеріали можуть розглядатися в якості радіаційно-стійких водневих поглиначів для зменшення ризиків, пов’язаних з витоком водню в аварійних умовах на атомних електростанціях.
Завантаження
##plugins.generic.usageStats.noStats##
Посилання
IAEA-TECDOC-1661. Mitigation of hydrogen hazards in severe accidents in Nuclear Power Plants http://www-pub.iaea.org/MTCD/publications/PDF/TE_1661_Web.pdf.
Yi.P. Bobrov, О.M. Bovda, O.Е. Dmytrenko, Hydrogen absorption-desorption behavior of melt-spun Ti30Zr45Ni25 alloy. Metallofizika i Noveyshye Tekhnologii 30 (2008) 329-336.
R.V. Azhazha, Yu.P. Bobrov, А.М. Bovda, A.E. Dmitrenko, Research of processes of sorption-desorption of hydrogen from the rapidly quenched alloys of the Ti-Zr-Ni system. VANT 17 (2008) 129-132.
J.Y. Kim, P.C. Gibbons , K.F. Kelton, Hydrogenation of Pd-coated samples of the Ti–Zr-based icosahedral phase and related crystalline phases, J. Alloys and Compounds 266 (1998) 311–317.
V.M. Azhazha, .D. Lavrinenko, Yu.F. Lоnіn, M.M. Pylypenko, B.V. Sereda, S.V. Kryachko,S.V. Malykhin, A.T. Pugachov, M.V. Reshetnyak, Changes of structure characteristics in Ti41,5Zr41,5Ni17 and Ti41,5Hf41,5Ni17 rapidly quenched ribbons under radiation influence, VANT, #2/97 (2011) 33-38.
E.H. Majzoubyz, R.G.Hennig and K.F. Kelton. Rietveld refinement and ab initio calculations of a C14-like Laves phase in Ti-Zr-Ni, Philosophical magazine letters, 83 (2003) 65–71.
I. P. Chernov, Yu. M. Koroteev., V. M. Silkin, Yu. I. Tyurin Excitation of Hydrogen Subsystem in Metals by External Influence, Proc. 8th Int. Workshop on Anomalies in Hydrogen / Deuterium Loaded Metals, (2007) p. 27-37.
J. F. R. Archilla, J. Cuevas, M. D. Alba, M. Naranjo, J. M. Trillo, Discrete breathers for understanding reconstructive mineral processes at low temperatures, J. Phys. Chem. B110 (2006) 24112-24120.
M. Haas, V. Hizhnyakov, A. Shelkan, M. Klopov, Prediction of high-frequency intrinsic localized modes in Ni and Nb, Phys. Rev. B, 84 (2011) 144303-1-8.
V. Hizhnyakov, M. Haas, A. Shelkan, M. Klopov, Theory and molecular dynamics simulations of intrinsic localized modes and defect formation in solids, Phys. Scr. 89 (2014) 044003-1-5.
L.Z. Khadeeva, S.V. Dmitriev, Discrete breathers in crystals with NaCl structure, Phys. Rev. B 81 (2010) 214306-1-8.
M.E. Manley, Impact of intrinsic localized modes of atomic motion on materials properties, Acta Materialia, 58 (2010) 2926-2935.
V. I. Dubinko, P. A. Selyshchev, and J. F. R. Archilla, Reaction-rate theory with account of the crystal anharmonicity, Phys. Rev. E 83 (2011) No 4, doi: 10.1103/PhysRevE.83.041124.
V.I. Dubinko, F.M. Russell, Radiation damage and recovery due to the interaction of crystal defects with anharmonic lattice excitations, J. Nuclear Materials, 419 (2011) 378-385.
V. I. Dubinko, A. V. Dubinko, Modification of reaction rates under irradiation of crystalline solids: contribution from intrinsic localized modes, Nuclear Inst. and Methods in Physics Research, B 303 (2013) 133–135.
V.I. Dubinko, F. Piazza, On the role of disorder in catalysis driven by discrete breathers, Letters on Materials (2014), 4 (2014) 273-278.
V. I. Dubinko, J. F. R. Archilla, S. V. Dmitriev, V. Hizhnyakov: Rate theory of acceleration of defect annealing driven by discrete breathers. In:
J.F.R. Archilla, N. Jiménez, Sánchez-Morcillo, L.M. García-Raffi (eds.) Quodons in mica: nonlinear localized travelling excitations in crystals. Springer (2015).
D. Terentyev, A. Dubinko, V. Dubinko, S. Dmitriev, E. Zhurkin, Interaction of discrete breathers with primary lattice defects in bcc Fe. Modelling Simul. Mater. Sci. Eng. 23 (2015) 085007-085030.
Yi.P. Bobrov, О.M. Bovda, O.Е. Dmytrenko, Hydrogen absorption-desorption behavior of melt-spun Ti30Zr45Ni25 alloy. Metallofizika i Noveyshye Tekhnologii 30 (2008) 329-336.
R.V. Azhazha, Yu.P. Bobrov, А.М. Bovda, A.E. Dmitrenko, Research of processes of sorption-desorption of hydrogen from the rapidly quenched alloys of the Ti-Zr-Ni system. VANT 17 (2008) 129-132.
J.Y. Kim, P.C. Gibbons , K.F. Kelton, Hydrogenation of Pd-coated samples of the Ti–Zr-based icosahedral phase and related crystalline phases, J. Alloys and Compounds 266 (1998) 311–317.
V.M. Azhazha, .D. Lavrinenko, Yu.F. Lоnіn, M.M. Pylypenko, B.V. Sereda, S.V. Kryachko,S.V. Malykhin, A.T. Pugachov, M.V. Reshetnyak, Changes of structure characteristics in Ti41,5Zr41,5Ni17 and Ti41,5Hf41,5Ni17 rapidly quenched ribbons under radiation influence, VANT, #2/97 (2011) 33-38.
E.H. Majzoubyz, R.G.Hennig and K.F. Kelton. Rietveld refinement and ab initio calculations of a C14-like Laves phase in Ti-Zr-Ni, Philosophical magazine letters, 83 (2003) 65–71.
I. P. Chernov, Yu. M. Koroteev., V. M. Silkin, Yu. I. Tyurin Excitation of Hydrogen Subsystem in Metals by External Influence, Proc. 8th Int. Workshop on Anomalies in Hydrogen / Deuterium Loaded Metals, (2007) p. 27-37.
J. F. R. Archilla, J. Cuevas, M. D. Alba, M. Naranjo, J. M. Trillo, Discrete breathers for understanding reconstructive mineral processes at low temperatures, J. Phys. Chem. B110 (2006) 24112-24120.
M. Haas, V. Hizhnyakov, A. Shelkan, M. Klopov, Prediction of high-frequency intrinsic localized modes in Ni and Nb, Phys. Rev. B, 84 (2011) 144303-1-8.
V. Hizhnyakov, M. Haas, A. Shelkan, M. Klopov, Theory and molecular dynamics simulations of intrinsic localized modes and defect formation in solids, Phys. Scr. 89 (2014) 044003-1-5.
L.Z. Khadeeva, S.V. Dmitriev, Discrete breathers in crystals with NaCl structure, Phys. Rev. B 81 (2010) 214306-1-8.
M.E. Manley, Impact of intrinsic localized modes of atomic motion on materials properties, Acta Materialia, 58 (2010) 2926-2935.
V. I. Dubinko, P. A. Selyshchev, and J. F. R. Archilla, Reaction-rate theory with account of the crystal anharmonicity, Phys. Rev. E 83 (2011) No 4, doi: 10.1103/PhysRevE.83.041124.
V.I. Dubinko, F.M. Russell, Radiation damage and recovery due to the interaction of crystal defects with anharmonic lattice excitations, J. Nuclear Materials, 419 (2011) 378-385.
V. I. Dubinko, A. V. Dubinko, Modification of reaction rates under irradiation of crystalline solids: contribution from intrinsic localized modes, Nuclear Inst. and Methods in Physics Research, B 303 (2013) 133–135.
V.I. Dubinko, F. Piazza, On the role of disorder in catalysis driven by discrete breathers, Letters on Materials (2014), 4 (2014) 273-278.
V. I. Dubinko, J. F. R. Archilla, S. V. Dmitriev, V. Hizhnyakov: Rate theory of acceleration of defect annealing driven by discrete breathers. In:
J.F.R. Archilla, N. Jiménez, Sánchez-Morcillo, L.M. García-Raffi (eds.) Quodons in mica: nonlinear localized travelling excitations in crystals. Springer (2015).
D. Terentyev, A. Dubinko, V. Dubinko, S. Dmitriev, E. Zhurkin, Interaction of discrete breathers with primary lattice defects in bcc Fe. Modelling Simul. Mater. Sci. Eng. 23 (2015) 085007-085030.
Опубліковано
2017-01-23
Як цитувати
Dmytrenko, O. E., Kolodiy, I. V., & Dubinko, V. I. (2017). Вплив гамма-опромінення на фізичні властивості прогонових розплаву сплавів Ti30Zr45Ni25. Вісник Харківського національного університету імені В. Н. Каразіна. Серія «Фізика», (24), 50-54. вилучено із https://periodicals.karazin.ua/physics/article/view/9206
3.gif){kind=logo}
