Kinetic Monte Carlo modelling of nano-oxide precipitation and its associated stability under neutron irradiation for the Fe-Ti-Y-O system

doi:10.1016/j.jmst.2024.08.066

Abstract

Abstract: While developing nuclear materials, predicting their behavior under long-term irradiation regimes spanning decades poses a significant challenge. We developed a novel Kinetic Monte Carlo (KMC) model to explore the precipitation behavior of Y-Ti-O oxides along grain boundaries within nanostructured ferritic alloys (NFA). This model also assessed the response of the oxides to neutron irradiation, even up simulated radiation damage levels in the desired long dpa range for reactor components. Our simulations investigated how temperature and grain boundary sinks influenced the oxide characteristics of a 12YWT-like alloy during heat treatments at 1023, 1123, and 1223 K. The oxide characteristics observed in our simulations were in good agreement with existing literature. Furthermore, the impact of grain boundaries on precipitation was found to be minimal. The resulting oxide configurations and positions were used in subsequent simulations that exposed them to simulated neutron irradiation to a total accumulated dose of 8 dpa at three temperatures: 673, 773, and 873 K, and at dose rates of 10^-3, 10^-4, and 10^-5 dpa/s. This demonstrated the expected inverse relationship between oxide size and dose rate. In a long-term irradiation simulation at 873 K and 10^-3 dpa/s was taken out to 66 dpa and found the oxides in the vicinity of the grain boundary were more susceptible to dissolution. Additionally, we conducted irradiation simulations of a 14YWT-like alloy to reproduce findings from neutron irradiation experiments. The larger oxides in the 14YWT-like alloy did not dissolve and displayed stability similar to the experimental results.

Key words: Ostwald ripening, ODS ferritic steel, Monte Carlo simulation, Irradiated metals

Chris Nellis, Céline Hin. Kinetic Monte Carlo modelling of nano-oxide precipitation and its associated stability under neutron irradiation for the Fe-Ti-Y-O system[J]. J. Mater. Sci. Technol., 2025, 222: 40-54.

References

[1] S.J. Zinkle, G.S. Was, Acta Mater. 61(2013) 735-758.
[2] K. Nordlund, S.J. Zinkle, A.E. Sand, F. Granberg, R.S. Averback, R.E. Stoller, T. Suzudo, L. Malerba, F. Banhart, W.J. Weber, F. Willaime, S.L. Dudarev, D. Simeone, J. Nucl. Mater. 512(2018) 450-479.
[3] A. Bhattacharya, S.J. Zinkle, J. Henry, S.M. Levine, P.D. Edmondson, M.R. Gilbert, H. Tanigawa, C.E. Kessel, J. Phys. Energy 4 (2022) 034003.
[4] G.R. Odette, M.J. Alinger, B.D. Wirth, Ann. Rev. Mater. Res. 38(2008) 471-503.
[5] M.J. Alinger, G.R. Odette, D.T. Hoelzer, Acta Mater. 57(2009) 392-406.
[6] M.K. Miller, K.F. Russell, D.T. Hoelzer, J. Nucl. Mater. 351(2006) 261-268.
[7] M.J. Alinger, On the Formation and Stability of Nanometer Scale Precipitates in Ferritic Alloys During Processing and High Temperature Service, Ph.D. Thesis, University of California, 2004.
[8] D. Pazos, M. Suárez, A. Fernández, P. Fernández, I. Iturriza, N. Ordás, Fusion Eng. Des. 146(2019) 2328-2333.
[9] A. Deschamps, F. De Geuser, J. Malaplate, D. Sornin, J. Nucl. Mater. 482(2016) 83-87.
[10] N. Cunningham, Y. Wu, D. Klingensmith, G.R. Odette, Mater. Sci. Eng. A 613 (2014) 296-305.
[11] J.P. Wharry, M.J. Swenson, K.H. Yano, J. Nucl. Mater. 486(2017) 11-20.
[12] J. Ribis, E. Bordas, P. Trocellier, Y. Serruys, J. Mater. Res. 30(2015) 1-12.
[13] M.J. Swenson, J.P. Wharry, J. Nucl. Mater. 467(2015) 97-112.
[14] K. Nordlund, J. Nucl. Mater. 520(2019) 273-295.
[15] C. Nellis, C. Hin, J. Alloy. Compd. 701(2017) 82-93.
[16] C.S. Becquart, A. De Backer, C. Domain, in: S. Schmauder, C.-S. Chen, K.K. Chawla, N. Chawla, W. Chen, Y. Kagawa (Eds.), Handbook of Mechanics of Ma-terials, Springer, Singapore, 2019, pp. 673-701.
[17] A. Dunn, R. Dingreville, E. Martínez, L. Capolungo, Comput. Mater. Sci. 120(2016) 43-52.
[18] F. Soisson, C.-C. Fu, Phys. Rev. B 76 (2007) 214102.
[19] C. Hin, Y. Bréchet, P. Maugis, F. Soisson, Acta Mater. 56(2008) 5653-5667.
[20] C. Hin, B.D. Wirth, J.B. Neaton, Phys. Rev. B 80 (2009) 134118.
[21] C. Hin, B.D. Wirth, Mater. Sci. Eng. A 528 (2011) 2056-2061.
[22] C. Nellis, C. Hin, J. Mater. Sci. 57(2022) 2710-2730.
[23] F. Soisson, J. Nucl. Mater. 349(2006) 235-250.
[24] C.S. Becquart, C. Domain, Phys. Status Solidi B 247 (2010) 9-22.
[25] E. Vincent, C.S. Becquart, C. Domain, J. Nucl. Mater. 382(2008) 154-159.
[26] Y. Jiang, J.R. Smith, G.R. Odette, Phys. Rev. B 79 (2009) 064103.
[27] M.J. Swenson, J.P. Wharry, JOM 72 (2020) 4017-4027.
[28] A. Seeger, Phys. Status Solidi A 167 (1998) 289-311.
[29] M. Mock, K. Albe, J. Nucl. Mater. 494(2017) 157-164.
[30] P. Klugkist, C. Herzig, Phys. Status Solidi A 148 (1995) 413-421.
[31] S.L. Shang, H.Z. Fang, J. Wang, C.P. Guo, Y. Wang, P.D. Jablonski, Y. Du, Z.K. Liu, Corros. Sci. 83(2014) 94-102.
[32] P. Lejček, S. Hofmann, J. Janovec, Mater. Sci. Eng. A 462 (2007) 76-85.
[33] D. Madland, A. Ignatyuk, Technol. Rep. 9 (2003) https://www.oecd-nea.org/upload/docs/application/pdf/2019-12/volume9.pdf.
[34] C.J. Ortiz, L. Luneville, D. Simeone, in: R.J.M. Konings, R.E. Stoller (Eds.), Com-prehensive Nuclear Materials, 2nd ed., Elsevier, Oxford, 2020, pp. 595-619.
[35] S.-Y. Zhong, J. Ribis, N. Lochet, de Carlan Y, V. Klosek, V. Ji, M.-H. Mathon, Met-all. Mater. Trans. A 46 (2015) 1413-1418.
[36] N. Akasaka, S. Yamashita, T. Yoshitake, S. Ukai, A. Kimura, J. Nucl. Mater.329-333(2004) 1053-1056.
[37] B. Cai, B.L. Adams, T.W. Nelson, Acta Mater. 55(2007) 1543-1553.
[38] J. Ribis, Y. de Carlan, Acta Mater. 60(2012) 238-252.
[39] J. Ribis, I. Mouton, C. Baumier, A. Gentils, M. Loyer-Prost, L. Luneville, D. Sime-one, Nanomaterials 11 (2021) 2590.
[40] R.V. Zucker, D. Chatain, U. Dahmen, S. Hagège, W.C. Carter, J. Mater. Sci. 47(2012) 8290-8302.
[41] J. Ribis, F. Leprêtre, Appl. Phys. Lett. 111(2017) 261602.
[42] E. Aydogan, J.S. Weaver, U. Carvajal-Nunez, M.M. Schneider, J.G. Gigax, D.L. Krumwiede, P. Hosemann, T.A .Saleh, N.A . Mara, D.T. Hoelzer, B. Hilton, S.A. Maloy, Acta Mater. 167(2019) 181-196.
[43] A. Certain, S. Kuchibhatla, V. Shutthanandan, D.T. Hoelzer, T.R. Allen, J. Nucl. Mater. 434(2013) 311-321.
[44] M.L. Lescoat, M.-L. Lescoat, J.Ribis, Y. Chen, E.A. Marquis, E. Bordas, P. Trocel-lier, Y. Serruys, A. Gentils, O. Kaïtasov, Y. de Carlan, A. Legris, Acta Mater. 78(2014) 328-340.
[45] T. Chen, J.G. Gigax, L. Price, D. Chen, S. Ukai, E. Aydogan, S.A. Maloy, F.A.Gar-ner, L.Shao, Acta Mater. 116(2016) 29-42.
[46] H. Wiedersich, P.R. Okamoto, N.Q. Lam, J. Nucl. Mater. 83(1979) 98-108.
[47] R.S. Nelson, J.A. Hudson, D.J. Mazey, J. Nucl. Mater. 44(1972) 318-330.
[48] J. Ribis, E. Bordas, P. Trocellier, Y. Serruys, Y. de Carlan, A. Legris, Nucl. In-strum. Methods Phys. Res. Sect. B-Beam Interact. Mater. Atoms 365 (2015) 22-25.
[49] J. Wang, M.B. Toloczko, V.N. Voyevodin, V.V. Bryk, O.V. Borodin, V.V. Mel'nychenko, A.S. Kalchenko, F.A. Garner, L. Shao, J. Nucl. Mater. 545(2021) 152528.
[50] T.R. Allen, J. Gan, J.I. Cole, M.K. Miller, J.T. Busby, S. Shutthanandan, S. The-vuthasan, J.Nucl. Mater. 375(2008) 26-37.
[51] K.G. Field, L.M. Barnard, C.M. Parish, J.T. Busby, D. Morgan, T.R. Allen, J. Nucl. Mater. 435(2013) 172-180.
[52] T. Schuler, D.R. Trinkle, P. Bellon, R. Averback, Phys. Rev. B 95 (2017) 174102.
[53] Y.G. Li, Y. Yang, M.P. Short, Z.J. Ding, Z. Zeng, J. Li, Sc . Rep. 5(2015) 18130.
[54] K. Nordlund, J. Wallenius, L. Malerba, Nucl. Instrum. Methods Phys. Res. Sect. B-Beam Interact. Mater. Atoms 246 (2006) 322-3326.
[55] G.H. Kinchin, R.S. Pease, Rep. Prog. Phys. 18(1955) 1-51 .