Kinetic Characteristics of Nitriding of Zr–1% Nb Alloy
We study the kinetic characteristics of nitriding of thin-sheet (~ 1 mm) samples of Zr–1% Nb alloy treated in a nitrogen atmosphere ( ) in broad temperature ( T = 550; 650; 750; 850 and 950°С) and time ( τ = 1; 5 and 10 h) ranges. It is shown that the process of nitriding of the analyzed alloy obeys...
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| Published in: | Materials science (New York, N.Y.) Vol. 58; no. 3; pp. 408 - 416 |
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| Abstract | We study the kinetic characteristics of nitriding of thin-sheet (~ 1 mm) samples of Zr–1% Nb alloy treated in a nitrogen atmosphere (
) in broad temperature (
T
= 550; 650; 750; 850 and 950°С) and time (
τ
= 1; 5 and 10 h) ranges. It is shown that the process of nitriding of the analyzed alloy obeys a law close to a parabolic dependence (
n
≈ 2). It is discovered that the activation energy of nitriding of the alloy within the temperature range 550–950°C is equal to 131.8 kJ/mole. The microstructure of the subsurface layer of the alloy after nitriding is analyzed. The distribution of the surface microhardness of Zr–1% Nb alloy is determined. The diagrams of intensity of the phase reflexes of
α
-Zr and ZrN on the surface of alloy after treatment in a nitrogen atmosphere are constructed. |
|---|---|
| AbstractList | We study the kinetic characteristics of nitriding of thin-sheet (~ 1 mm) samples of Zr–1% Nb alloy treated in a nitrogen atmosphere () in broad temperature (T = 550; 650; 750; 850 and 950°С) and time (τ = 1; 5 and 10 h) ranges. It is shown that the process of nitriding of the analyzed alloy obeys a law close to a parabolic dependence (n ≈ 2). It is discovered that the activation energy of nitriding of the alloy within the temperature range 550–950°C is equal to 131.8 kJ/mole. The microstructure of the subsurface layer of the alloy after nitriding is analyzed. The distribution of the surface microhardness of Zr–1% Nb alloy is determined. The diagrams of intensity of the phase reflexes of α-Zr and ZrN on the surface of alloy after treatment in a nitrogen atmosphere are constructed. We study the kinetic characteristics of nitriding of thin-sheet (~ 1 mm) samples of Zr-1% Nb alloy treated in a nitrogen atmosphere ( [Formula omitted]) in broad temperature (T = 550; 650; 750; 850 and 950°Ð¡) and time ([tau] = 1; 5 and 10 h) ranges. It is shown that the process of nitriding of the analyzed alloy obeys a law close to a parabolic dependence (n [almost equal to] 2). It is discovered that the activation energy of nitriding of the alloy within the temperature range 550-950°C is equal to 131.8 kJ/mole. The microstructure of the subsurface layer of the alloy after nitriding is analyzed. The distribution of the surface microhardness of Zr-1% Nb alloy is determined. The diagrams of intensity of the phase reflexes of [alpha]-Zr and ZrN on the surface of alloy after treatment in a nitrogen atmosphere are constructed. We study the kinetic characteristics of nitriding of thin-sheet (~ 1 mm) samples of Zr–1% Nb alloy treated in a nitrogen atmosphere ( ) in broad temperature ( T = 550; 650; 750; 850 and 950°С) and time ( τ = 1; 5 and 10 h) ranges. It is shown that the process of nitriding of the analyzed alloy obeys a law close to a parabolic dependence ( n ≈ 2). It is discovered that the activation energy of nitriding of the alloy within the temperature range 550–950°C is equal to 131.8 kJ/mole. The microstructure of the subsurface layer of the alloy after nitriding is analyzed. The distribution of the surface microhardness of Zr–1% Nb alloy is determined. The diagrams of intensity of the phase reflexes of α -Zr and ZrN on the surface of alloy after treatment in a nitrogen atmosphere are constructed. |
| Audience | Academic |
| Author | Luk’yanenko, A. G. Stoev, P. I. Kovalchuk, I. V. Pohrelyuk, I. M. Trush, V. S. Fedirko, V. M. Kravchyshyn, T. M. |
| Author_xml | – sequence: 1 givenname: V. S. surname: Trush fullname: Trush, V. S. email: trushvasyl@gmail.com organization: Karpenko Physicomechanical Institute, National Academy of Sciences of Ukraine – sequence: 2 givenname: I. M. surname: Pohrelyuk fullname: Pohrelyuk, I. M. organization: Karpenko Physicomechanical Institute, National Academy of Sciences of Ukraine – sequence: 3 givenname: T. M. surname: Kravchyshyn fullname: Kravchyshyn, T. M. organization: Karpenko Physicomechanical Institute, National Academy of Sciences of Ukraine – sequence: 4 givenname: A. G. surname: Luk’yanenko fullname: Luk’yanenko, A. G. organization: Karpenko Physicomechanical Institute, National Academy of Sciences of Ukraine – sequence: 5 givenname: P. I. surname: Stoev fullname: Stoev, P. I. organization: Institute of Solid-State Physics, Materials Science, and Technologies, “KhFTI” National Science Center, National Academy of Sciences of Ukraine – sequence: 6 givenname: V. M. surname: Fedirko fullname: Fedirko, V. M. organization: Karpenko Physicomechanical Institute, National Academy of Sciences of Ukraine – sequence: 7 givenname: I. V. surname: Kovalchuk fullname: Kovalchuk, I. V. organization: Karpenko Physicomechanical Institute, National Academy of Sciences of Ukraine |
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| Cites_doi | 10.1002/9783527603978.mst0111 10.1039/c5cp02252e 10.1146/annurev-matsci-070214-020951 10.1007/BF02647575 10.1007/s11041-015-9818-1 10.1016/j.ceramint.2011.11.07 10.1007/s11003-020-00342-z 10.1007/s11003-021-00457-x 10.1007/s11003-016-9945-x 10.15544/balttrib.2017.09 10.1016/j.surfcoat.2013.09.04 10.1016/j.scriptamat.2016.02.021 10.1016/В978-0-12-803581-8.02576-5 |
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Orlov, et al., Mechanical Engineering in Nuclear Engineering [in Russian], Vol. IV-25, Book 1 in: Mechanical Engineering. Encyclopedia, Mashinostroenie, Moscow (2005). V. M. Fedirko, O. H. Luk’yanenko, V. S. Trush, P. I. Stoev, and M. A. Tykhonovs’kyi, “Effect of thermochemical treatment in regulated gas media on the thermal resistance of Zr–1%Nb alloy,” Mater. Sci.,52, No. 2, 209–215 (2016); DOI: https://doi.org/10.1007/s11003-016-9945-x. MottaATCouetAComstockRJCorrosion of zirconium alloys used for nuclear fuel claddingAnnual Rev. Mat. Res.2015453113431:CAS:528:DC%2BC2MXhtFWqurrJ10.1146/annurev-matsci-070214-020951 V. S. Vakhrusheva, O. A. Kolenkova, and G. D. Sukhomlin, “Influence of oxygen content on the plasticity, damageability, and the parameters of acoustic emission of the metal of pipes made of Zr–1%Nb alloy,” in: Vopr. Atom. Nauk. Tekh.. Ser.: Fiz. Radiats. Povrezhd. Radiats. Materialoved., No. 5 (88) (2005), pp. 104–109. Z. Z. 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Phys., No. 17 (26), 17301–17310 (2015); DOI:https://doi.org/10.1039/c5cp02252e. BelousVAVyugovPNKuprinASLeonovSANosovGIOvcharenkoVDOzhigovLSRudenkoAGSavchenkoVITolmachevaGNKhoroshikhVMInvestigation of the influence of ion-plasma processing on the mechanical characteristics of Zr1Nb zirconium alloyFiz. Inzhener. Poverkh.201311197102 I. M. Pohrelyuk, J. Padgurskas, S. M. Lavrys, A. G. Luk’yanenko, V. S. Trush, and R. Kreivaitis, “Topography, hardness, elastic modulus and wear resistance of nitride on titanium,” in: Proc. of the 9th Internat. Conf. BALTTRIB’2017, (November, 16–17, 2017), A. Stulginskis Univ., Kaunas (2017), pp. 41–46; DOI:10.15544/balttrib.2017.09. ZaimovskiiASNikulinaAVReshetnikovNGZirconium Alloys in Nuclear Power Engineering1994MoscowÉnergoatomizdat[in Russian] V. M. Voyevodin, V. M. Fedirko, V. S. Trush, O. H. Luk’yanenko, P. I. Stoev, V. A. Panov, M. А. 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| References_xml | – reference: I. M. Pohrelyuk, J. Padgurskas, S. M. Lavrys, A. G. Luk’yanenko, V. S. Trush, and R. Kreivaitis, “Topography, hardness, elastic modulus and wear resistance of nitride on titanium,” in: Proc. of the 9th Internat. Conf. BALTTRIB’2017, (November, 16–17, 2017), A. Stulginskis Univ., Kaunas (2017), pp. 41–46; DOI:10.15544/balttrib.2017.09. – reference: О. М. Ivasishin, V. N. Voevodin, А. I. Dekhtyar, P. E. Markovsky, M. M. Pylypenko, S. D. Lavrinenko, and R. G. Gontareva, “Features of the mechanical behavior of fuel elements tubes of Zr–1%Nb under conditions simulating breakdown of cooling,” Probl. Atomic Sci. Technol., No. 5 (99), 53–60 (2015). – reference: S. Banerjee and M. K. Banerjee, “Nuclear applications: zirconium alloys,” Reference Module Mater. Sci. Mater. Eng., 1–15 (2016); DOI:https://doi.org/10.1016/В978-0-12-803581-8.02576-5. – reference: Z. Z. Tang, “Effect of nitrogen concentration to the structural, chemical and electrical properties of tantalum zirconium nitride films,” Ceramics Int., No. 38 (4), 2997–3000 (2012); DOI:https://doi.org/10.1016/j.ceramint.2011.11.07. – reference: AzarenkovNАBulavinLАZalyubovskiiIIKirichenkoVGNeklyudovIМShilyaevBАNuclear Power Engineering: A Textbook2012KharkovKarazin Kharkov National University[in Russian] – reference: V. M. Voyevodin, V. M. Fedirko, V. S. Trush, O. H. Luk’yanenko, P. I. Stoev, V. A. Panov, M. А. Tykhonovsky, “Influence of thermochemical treatment on the oxidation of fuel cladding tubes made of Zr–1%Nb alloy,” Mater. Sci.,56, No. 4, 509–515 (2021); DOI:https://doi.org/10.1007/s11003-021-00457-x. – reference: TrushVSLukianenkoОHStoevPІInfluence of modification of the surface layer by penetrating impurities on the long-term strength of Zr–1% Nb alloyMater. Sci.20205545855891:CAS:528:DC%2BB3cXpt1yktrc%3D10.1007/s11003-020-00342-z – reference: V. M. Fedirko, O. H. Luk’yanenko, V. S. Trush, P. I. Stoev, and M. A. Tykhonovs’kyi, “Effect of thermochemical treatment in regulated gas media on the thermal resistance of Zr–1%Nb alloy,” Mater. Sci.,52, No. 2, 209–215 (2016); DOI: https://doi.org/10.1007/s11003-016-9945-x. – reference: ChossonRGourgues-LorenzonAFVandenbergheVBrachetJCCrépinJCreep flow and fracture behavior of the oxygen-enriched alpha phase in zirconium alloysScripta Mater.201611720231:CAS:528:DC%2BC28XksFCrtbs%3D10.1016/j.scriptamat.2016.02.021 – reference: L. Gribaudo, D. Arias, and J. Abriata, “The N–Zr (Nitrogen–Zirconium) system,” J. Phase Equilibria,15, No. 4, 441–449 (1994). – reference: DubeyPAryaVSrivastavaSSinghDChandraREffect of nitrogen flow rate on structural and mechanical properties of zirconium tungsten nitride (Zr–W–N) coatings deposited by magnetron sputteringSurf. Coat. Technol.20132361821871:CAS:528:DC%2BC3sXhs1Wiu7zF10.1016/j.surfcoat.2013.09.04 – reference: J. Zhang, A. R. Oganov, X. Li, H. Dong, and Q. Zeng, “Novel compounds in the Zr–O system, their crystal structures and mechanical properties,” Phys. Chem. Chem. Phys., No. 17 (26), 17301–17310 (2015); DOI:https://doi.org/10.1039/c5cp02252e. – reference: T. P. Chernyaeva, A. I. Stukalov, and V. M. Gritsina, “Influence of oxygen on the mechanical properties of zirconium,” Vopr. Atom. Nauki Tekh., Ser. Vakuum, Chist. Mater., Sverkhprovodniki, No. 1 (12), 96–102 (2002). – reference: V. N. Fedirko, A. G. Luk’yanenko, and V. S. Trush, “Solid-solution hardening of the surface layer of titanium alloys. Part 2. Effect on metallophysical properties,” Metal Sci. Heat Treatm.,56, No. 11, 661–664 (2015); DOI: https://doi.org/10.1007/s11041-015-9818-1. – reference: V. S. Trush, V. N. Fedirko, A. G. Luk’yanenko, M. A. Tikhonovsky, and P. I. Stoev, “Influence of thermochemical treatment on properties of tubes from Zr–1Nb alloy,” Probl. Atomic Sci. 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| Snippet | We study the kinetic characteristics of nitriding of thin-sheet (~ 1 mm) samples of Zr–1% Nb alloy treated in a nitrogen atmosphere (
) in broad temperature (... We study the kinetic characteristics of nitriding of thin-sheet (~ 1 mm) samples of Zr-1% Nb alloy treated in a nitrogen atmosphere ( [Formula omitted]) in... We study the kinetic characteristics of nitriding of thin-sheet (~ 1 mm) samples of Zr–1% Nb alloy treated in a nitrogen atmosphere () in broad temperature (T... |
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| SubjectTerms | Alloys Characterization and Evaluation of Materials Chemistry and Materials Science Materials Science Microhardness Niobium base alloys Nitriding Nitrogen Reflexes Solid Mechanics Specialty metals industry Structural Materials Zirconium base alloys |
| Title | Kinetic Characteristics of Nitriding of Zr–1% Nb Alloy |
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