The self-ion irradiation effects in 6061-Al alloy

Zhanfeng Yan; Jian Zheng; Wei Zhou; Hao Wang

doi:10.11884/HPLPB202234.210509

[1] Garric V, Colas K, Donnadieu P, et al. Impact of the microstructure on the swelling of aluminum alloys: characterization and modelling bases[J]. Journal of Nuclear Materials, 557, 153273(2021).

[2] Soria S R, Tolley A, Sánchez E A. The influence of microstructure on blistering and bubble formation by He ion irradiation in Al alloys[J]. Journal of Nuclear Materials, 467, 357-367(2015).

[3] Yu Jinnan. Radiation effects in materials[M]. Beijing: Chemical Industry Press, 2007

[4] Sturcken E F. Irradiation effects in magnesium and aluminum alloys[J]. Journal of Nuclear Materials, 82, 39-53(1979).

[5] King R T, Jostsons A. Irradiation damage in a 2.2 pct magnesium-aluminum alloy[J]. Metallurgical Transactions A, 6, 863-868(1975).

[6] Kamigaki N, Furuno S, Hojou K, et al. Evolution of structural damage in aluminum alloys irradiated with helium ions[J]. Journal of Nuclear Materials, 191/194, 1214-1218(1992).

[7] Was G S. Challenges to the use of ion irradiation for emulating reactor irradiation[J]. Journal of Materials Research, 30, 1158-1182(2015).

[8] Jiao Z, Michalicka J, Was G S. Self-ion emulation of high dose neutron irradiated microstructure in stainless steels[J]. Journal of Nuclear Materials, 501, 312-318(2018).

[9] Pareige C, Kuksenko V, Pareige P. Behaviour of P, Si, Ni impurities and Cr in self ion irradiated Fe–Cr alloys – Comparison to neutron irradiation[J]. Journal of Nuclear Materials, 456, 471-476(2015).

[10] Was G S, Jiao Z, Getto E, et al. Emulation of reactor irradiation damage using ion beams[J]. Scripta Materialia, 88, 33-36(2014).

[11] Zinkle S J, Snead L L. Opportunities and limitations for ion beams in radiation effects studies: bridging critical gaps between charged particle and neutron irradiations[J]. Scripta Materialia, 143, 154-160(2018).

[12] Stoller R E, Toloczko M B, Was G S, et al. On the use of SRIM for computing radiation damage exposure[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 310, 75-80(2013).

[13] Oliver W C, Pharr G M. An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments[J]. Journal of Materials Research, 7, 1564-1583(1992).

[14] Oliver W C, Pharr G M. Measurement of hardness and elastic modulus by instrumented indentation: advances in understanding and refinements to methodology[J]. Journal of Materials Research, 19, 3-20(2004).

[15] Li Xiaodong, Bhushan B. A review of nanoindentation continuous stiffness measurement technique and its applications[J]. Materials Characterization, 48, 11-36(2002).

[16] Liu Xiangbing, Wang Rongshan, Ren Ai, et al. Evaluation of radiation hardening in ion-irradiated Fe based alloys by nanoindentation[J]. Journal of Nuclear Materials, 444, 1-6(2014).

[17] Wang Guanghou. Particlesolid interaction physics[M]. Beijing: Science Press, 1991

[18] Osetsky Y N, Bacon D J, Serra A, et al. Stability and mobility of defect clusters and dislocation loops in metals[J]. Journal of Nuclear Materials, 276, 65-77(2000).

[19] Singh B N, Foreman A J E, Trinkaus H. Radiation hardening revisited: role of intracascade clustering[J]. Journal of Nuclear Materials, 249, 103-115(1997).

[20] Guo Liping, Luo Fengfeng, Yu Yanxia. Dislocation loops in irradiated nuclear materials[M]. Beijing: National Defense Industry Press, 2017

[21] Changizian P, Zhang H K, Yao Z. Effect of simultaneous helium implantation on the microstructure evolution of Inconel X-750 superalloy during dual-beam irradiation[J]. Philosophical Magazine, 95, 3933-3949(2015).

[22] Tartour J P, Washburn J. Climb kinetics of dislocation loops in aluminium[J]. The Philosophical Magazine:A Journal of Theoretical Experimental and Applied Physics, 18, 1257-1267(1968).

[23] Yang Tengfei, Guo Wei, Poplawsky J D, et al. Structural damage and phase stability of Al_0.3CoCrFeNi high entropy alloy under high temperature ion irradiation[J]. Acta Materialia, 188, 1-15(2020).

[24] Lu Chenyang, Yang Taini, Jin Ke, et al. Radiation-induced segregation on defect clusters in single-phase concentrated solid-solution alloys[J]. Acta Materialia, 127, 98-107(2017).

[25] Xiu Pengyuan, Bei Hongbin, Zhang Yanwen, et al. STEM characterization of dislocation loops in irradiated FCC alloys[J]. Journal of Nuclear Materials, 544, 152658(2021).

[26] Murakami S, Miyazaki A, Mizuno M. Modeling of irradiation embrittlement of reactor pressure vessel steels[J]. Journal of Engineering Materials and Technology, 122, 60-66(2000).

[27] Yamamoto T, Odette G R, Kishimoto H, et al. On the effects of irradiation and helium on the yield stress changes and hardening and non-hardening embrittlement of ～8Cr tempered martensitic steels: compilation and analysis of existing data[J]. Journal of Nuclear Materials, 356, 27-49(2006).

[28] Pharr G M, Herbert E G, Gao Y F. The indentation size effect: a critical examination of experimental observations and mechanistic interpretations[J]. Annual Review of Materials Research, 40, 271-292(2010).

[29] Wei Y P, Liu P P, Zhu Y M, et al. Evaluation of irradiation hardening and microstructure evolution under the synergistic interaction of He and subsequent Fe ions irradiation in CLAM steel[J]. Journal of Alloys and Compounds, 676, 481-488(2016).

[30] Konings R J M, Allen T R, Stoller R E, et al. Comprehensive nuclear materials[M]. Amsterdam: Elsevier Science, 2012.

[31] Huang H F, Li D H, Li J J, et al. Nanostructure variations and their effects on mechanical strength of Ni-17Mo-7Cr alloy under xenon ion irradiation[J]. Materials Transactions, 55, 1243-1247(2014).

[32] Heintze C, Bergner F, Hernández-Mayoral M. Ion-irradiation-induced damage in Fe-Cr alloys characterized by nanoindentation[J]. Journal of Nuclear Materials, 417, 980-983(2011).

CLP Journals