Effect of dose rate on the characteristics of dislocation loops in palladium: In-situ TEM analysis during 30 keV H2+ irradiation

doi:10.1016/j.jmst.2022.12.013

Abstract

Abstract: Ion irradiation is usually used to simulate neutron irradiation to accelerate the evaluation of the irradiation behavior of reactor materials. However, the validity of using a high damage rate of ion irradiation to simulate a low damage rate of neutron irradiation has always been a controversial topic. Here, the effect of two dose rates (2.94 × 10^-6 and 7.35 × 10^-5 dpa s^-1) on the characteristics and evolution of dislocation loops in palladium was studied in situ during 30 keV H₂⁺ irradiation using transmission electron microscopy. The dose rate obviously affected the nucleation rate and growth rate of dislocation loops, the types (Frank loops or perfect loops) of dislocation loops, and the irradiation hardening and total damage obtained from the product of average loop size and loop density. At the same irradiation dose, a high dose rate would lead to high loop density, small average loop size, low loop growth rate, and low irradiation hardening and damage induced by loops in pure Pd. Meanwhile, it was found for the first time that a high dose rate was beneficial to the generation of perfect dislocation loops. The effect of dose rate was attributed to the different dynamic equilibrium results between the effective generation rate of point defects and their absorption rate by existing sinks. The present results show that the effect of dose rate should be considered when using ion irradiation to simulate neutron irradiation to evaluate the irradiation damage to materials.

Key words: Palladium, Hydrogen irradiation, In-situ TEM observation, Dislocation loop, Dose rate

Dewang Cui, Ziqi Cao, Yifan Ding, Yipeng Li, Guang Ran. Effect of dose rate on the characteristics of dislocation loops in palladium: In-situ TEM analysis during 30 keV H₂⁺ irradiation[J]. J. Mater. Sci. Technol., 2023, 150: 86-95.

References

[1] Z.B. Zhu, W.C. Ji, H.F. Huang, J. Nucl. Mater. 560(2022) 153506.
[2] H.Y. Fan, Y.W. You, W.Y. Ni, Q. Yang, L. Liu, G. Benstetter, D.P. Liu, C.S. Liu, Sci. Rep. 6(2016) 23738.
[3] X.L. Zhu, Y. Zhang, L. Cheng, Y. Yuan, G. De Temmerman, B.Y. Wang, X.Z. Cao, G.H. Lu, Nucl. Fusion 56 (2016) 036010.
[4] R.Y. Zheng, W.Z. Han, Acta Mater. 186(2020) 162-171.
[5] K. Bawane, K. Lu, X.M. Bai, J. Hu, M.M. Li, P.M. Baldo, E. Ryan, J. Mater. Sci.Technol. 71(2021) 75-83.
[6] K.G. Field, X.X. Hu, K.C. Littrell, Y. Yamamoto, L.L. Snead, J. Nucl. Mater. 465(2015) 746-755.
[7] Y.P. Lu, H.F. Huang, X.Z. Gao, C.L. Ren, J. Gao, H.Z. Zhang, S.J. Zheng, Q.Q. Jin, Y.H. Zhao, C.Y. Lu, T.M. Wang, T.J. Li, J. Mater. Sci.Technol. 35(2019) 369-373.
[8] C.Y. Lu, M.Y. Li, P.Y. Xiu, X. Wang, G. Velişa, L.Jiang, K.L. More, J.D. Poplawsky, Y.Q. Chang, Y.W. Zhang, L.M. Wang, J. Nucl. Mater. 557(2021) 153316.
[9] C.Y. Lu, L.L. Niu, N.J. Chen, K. Jin, T.N. Yang, P.Y. Xiu, Y.W. Zhang, F. Gao, H.B. Bei, S. Shi, M.R. He, L.M. Robertson, W.J. Weber, L.M. Wang, Nat. Commun. 7(2016) 13564.
[10] L.Q. Liu, X.J. Liu, Q. Du, H. Wang, Y. Wu, S.H. Jiang, Z.P. Lu, J. Mater. Sci.Technol. 135(2023) 13-25.
[11] Y.F. Zhao, H.H. Chen, D.D. Zhang, J.Y. Zhang, Y.Q. Wang, K. Wu, G. Liu, J. Sun, J. Mater. Sci.Technol. 116(2022) 199-213.
[12] X. Zhou, H. Wang, L.P. Guo, Y.H. Chen, F. Li, Y.X. Long, C. Chen, Z.Y. Xie, H.T. Luo, S.B. Mo, J. Mater. Sci.Technol. 95(2021) 181-192.
[13] G.S. Was, Z. Jiao, E. Getto, K. Sun, A.M. Monterrosa, S.A. Maloy, O. Anderoglu, B.H. Sencer, M. Hackett, Scr. Mater. 88(2014) 33-36.
[14] M.M. Li, M.A. Kirk, P.M. Baldo, D.H. Xu, B.D. Wirth, Philos. Mag. 92(2012) 2048-2078.
[15] Y.P. Li, G. Ran, X.Y. Liu, Q. Han, X.Y. Huang, Y.F. Ding, J. Mater. Sci.Technol. 107(2022) 14-25.
[16] X.O. Yi, M.L. Jenkins, K. Hattar, P.D. Edmondson, S.G. Roberts, Acta Mater. 92(2015) 163-177.
[17] G.S. Was, J. Mater. Res. 30(2015) 1158-1182.
[18] W.L. Jiang, Y.Y. Zhu, L.M. Zhang, D.J. Edwards, N.R. Overman, G. Nandipati, W. Setyawan, C.H.Henager Jr, R.J. Kurtz, J. Nucl. Mater. 550(2021) 152905.
[19] A. Kamboj, E.A. Marquis, Scr. Mater. 215(2022) 114697.
[20] K. Fujii, K. Fukuya, T. Hojo, J. Nucl. Sci.Technol. 50(2013) 160-168.
[21] Y.P. Li, G. Ran, Y.J. Guo, Z.P. Sun, X.Y. Liu, Y.M. Li, X. Qiu, Y. Xin, Acta Mater. 201(2020) 462-476.
[22] J.Y. Li, C.H. Zhang, Y.T. Yang, T.S. Wang, I. Martin-Bragado, J. Nucl. Mater. 561(2022) 153529.
[23] S.L. Dudarev, K. Arakawa, X. Yi, Z. Yao, M. Jenkins, M. Gilbert, P. Derlet, J. Nucl. Mater. 455(2014) 16-20.
[24] S.P. Shu, N. Almirall, P.B. Wells, T. Yamamoto, G.R. Odette, D.D. Morgan, Acta Mater. 157(2018) 72-82.
[25] L. Boulanger, Y. Serruys, J. Nucl. Mater. 386 (2009) 441-444.
[26] D.Y. Chen, K. Murakami, H.L. Yang, L. Chen, H. Abe, Z.C. Li, N. Sekimura, Scr. Mater. 207(2022) 114311.
[27] C.D. Hardie, C.A. Williams, S. Xu, S.G. Roberts, J. Nucl. Mater. 439(2013) 33-40.
[28] Y.F. Ding, G. Ran, Y.P. Li, Z.Q. Cao, D.W. Cui, J.C. Huang, Z.H. Zhou, Scr. Mater. 222(2023) 115054.
[29] O. El-Atwani, E. Esquivel, M. Efe, E. Aydogan, Y.Q. Wang, E. Martinez, S.A. Maloy, Acta Mater. 149(2018) 206-219.
[30] X.Y. Liu, Y.P. Li, G. Ran, Q. Han, P.H. Chen, Mater. Today Energy 21 (2021) 100731.
[31] Y.P. Li, G. Ran, Q. Han, Y. Xin, X.Y. Liu, X.Q. Ye, Scr. Mater. 203(2021) 114047.
[32] S.H. Li, N. Gao, W.Z. Han, J. Mater. Sci.Technol. 58(2020) 114-119.
[33] S.M. Liu, S.H. Li, W.Z. Han, J. Mater. Sci.Technol. 35(2019) 1466-1472.
[34] S.X. Jin, L.P. Guo, Y.Y. Ren, R. Tang, Y.X. Qiao, J. Mater. Sci.Technol. 28(2012) 1039-1045.
[35] A. Etienne, M. Hernández-Mayoral, C. Genevois, B. Radiguet, P. Pareige, J. Nucl. Mater. 400(2010) 56-63.
[36] C. Dai, Q. Wang, P. Saidi, B. Langelier, C.D. Judge, M.R. Daymond, M.A. Mattucci, J. Nucl. Mater. 563(2022) 153636.
[37] P.Y. Xiu, H.B. Bei, Y.W. Zhang, L.M. Wang, K.G. Field, J. Nucl. Mater. 544(2021) 152658.
[38] Y.N. Osetsky, A. Serra, B.N. Singh, S.I. Golubov, Philos. Mag. A 80 (2000) 2131-2157.
[39] Y. Luo, Y.Y. Dong, X.T. Wang, H. Peng, D.P. Yan, T. Hu, S.L. Zhang, Q.Y. Li, D. Wang, C. Xiao, J. Nucl. Mater. 559(2022) 153420.
[40] Y. Xin, T.D. Ma, X. Ju, J. Qiu, J. Mater. Sci.Technol. 29(2013) 467-470.
[41] M.J. Huang, Y.P. Li, G. Ran, Z.B. Yang, P.H. Wang, J. Nucl. Mater. 538(2020) 152240.
[42] R.E. Stoller, M.B. Toloczko, G.S. Was, A.G. Certain, S. Dwaraknath, F.A. Garner, Nucl. Instrum. Methods Phys. Res. B 310 (2013) 75-80.
[43] C.M. Jimenez, L.F. Lowe, E.A. Burke, C. Sherman, Phys. Rev. 153(1967) 735.
[44] C. Pokor, Y. Brechet, P. Dubuisson, J.P. Massoud, A. Barbu, J. Nucl. Mater. 326(2004) 19-29.
[45] P.J. Maziasz, C.J.McHargue, Int.Mater. Rev. 32(1987) 190-219.
[46] F.F. Luo, L.P. Guo, J.H. Chen, T.C. Li, Z.C. Zheng, Z. Yao, J.P. Suo, J. Nucl. Mater. 455(2014) 339-342.
[47] J.C. Haley, S.A. Briggs, P.D. Edmondson, K. Sridharan, S.G. Roberts, S. Lozano-Perez, K.G. Field, Acta Mater. 136(2017) 390-401.
[48] J. Schindelin, I. Arganda-Carreras, E. Frise, V. Kaynig, M. Longair, T. Pietzsch, S. Preibisch, C. Rueden, S. Saalfeld, B. Schmid, J. Tinevez, D.J. White, V. Harten- stein, K. Eliceiri, P. Tomancak, A. Cardona, Nat. Methods 9 (2012) 676-682.
[49] B. Yao, D.J. Edwards, R.J. Kurtz, J. Nucl. Mater. 434(2013) 402-410.
[50] Y.P. Li, M.S. Yu, G. Ran, N. Gao, Y. Chen, Q. Han, H. Wang, Z.H. Zhou, J.C. Huang, Mater. Today Energy 21 (2021) 100788.
[51] Z.Q. Cao, G. Ran, Z. Wang, Y.P. Li, X.Y. Wu, L. Wu, X.Y. Huang, H.J. Mo, J. Mater. Sci.Technol. 123(2022) 49-59.
[52] Z.B. Zhu, W.C. Ji, H.F. Huang, J. Mater. Sci.Technol. 138(2023) 36-49.
[53] R.J. Gaboriaud, J. Grilhé, Phys. Status Solidi B 51 (1972) 579-587.
[54] D. Mordehai, G. Martin, Phys. Rev. B 84 (2011) 014115.
[55] R. Schäublin, Z. Yao, N. Baluc, M. Victoria, Philos. Mag. 85(2005) 769-777.
[56] S.L. Dudarev, M.R. Gilbert, K. Arakawa, H. Mori, Z. Yao, M.L. Jenkins, P.M. Derlet, Phys. Rev. B 81 (2010) 224107.
[57] K. Nordlund, R.S. Averback, Phys. Rev. Lett. 80(1998) 4201.
[58] C. Abromeit, J. Nucl. Mater. 216(1994) 78-96.
[59] C.H. Woo, B.N. Singh, Philos. Mag. A 65 (1992) 889-912.
[60] M.J. Norgett, M.T. Robinson, I.M. Torrens, Nucl. Eng. Des. 33(1975) 50-54.
[61] P. Heald, M.V. Speight, Acta Metall. 23(1975) 1389-1399.
[62] N. Soneda, S. Ishino, A. Takahashi, K. Dohi, J. Nucl. Mater. 323(2003) 169-180.
[63] Y.P. Li, L. Wang, G. Ran, Y. Yuan, L. Wu, X.Y. Liu, X. Qiu, Z.P. Sun, Y.F. Ding, Q. Han, X.Y. Wu, H.Q. Deng, X.Y. Huang, Acta Mater. 206(2021) 116618.
[64] Q. Han, Y.P. Li, G. Ran, X.Y. Liu, L. Wu, Y. Chen, P.H. Chen, X.Q. Ye, Y.F. Ding, X. Y. Wu, J. Mater. Sci.Technol. 87(2021) 108-119.
[65] Y.N. Osetsky, D.J. Bacon, A. Serra, B.N. Singh, S.I. Golubov, J. Nucl. Mater. 276(20 0 0) 65-77.
[66] W.J. Phythian, R.E. Stoller, A.J.E.Foreman, A.F. Calder, D.J. Bacon, J. Nucl. Mater. 223(1995) 245-261.
[67] Y.N. Osetsky, D.J. Bacon, A. Serra, B.N. Singh, S.I. Golubov, Philos. Mag. 83(2003) 61-91.
[68] M. Grifﬁths, Philos. Mag. A 63 (1991) 835-847.
[69] T.A. Khraishi, J.P. Hirth, H.M. Zbib, T.D. de La Rubia, Philos.Mag. Lett. 80(20 0 0) 95-105.
[70] Y.L. Li, S.Y. Hu, C.H.Henager Jr, H.Q. Deng, F. Gao, X. Sun, M.A. Khaleel, J. Nucl. Mater. 427(2012) 259-267.
[71] K. Nordlund, F. Djurabekova, G. Hobler, Phys. Rev. B 94 (2016) 214109.
[72] M. Lambrecht, E. Meslin, L. Malerba, M. Hernández-Mayoral, F. Bergner, P. Pareige, B. Radiguet, A. Almazouzi, J. Nucl. Mater. 406(2010) 84-89.
[73] O. El-Atwani, W.S. Cunningham, E. Esquivel, M. Li, J.R. Trelewicz, B.P. Uberuaga, S.A. Maloy, Acta Mater. 164(2019) 547-559.
[74] S. Teysseyre, Z. Jiao, E. West, G.S. Was, J. Nucl. Mater. 371(2007) 107-117.
[75] G.R. Odette, T. Yamamoto, D. Klingensmith, Philos. Mag. 85(2005) 779-797.
[76] R. Sizmann, J. Nucl. Mater. 69(1978) 386-412.
[77] N. Soneda, in: Irradiation Embrittlement of Reactor Pressure Vessels (RPVs) in Nuclear Power Plants, Woodhead Publ Ltd, Cambridge, England, 2015, pp. 333-377.
[78] K. Ma, B. Décamps, A. Fraczkiewicz, T. Jourdan, F. Prima, M. Loyer-Prost, Acta Mater. 212(2021) 116874.

Effect of dose rate on the characteristics of dislocation loops in palladium: In-situ TEM analysis during 30 keV H₂⁺ irradiation

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