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Stacking fault tetrahedron (SFT) is a common type of three-dimensional vacancy clustered defect in irradiated FCC metals and alloys, which has a great influence on the mechanical properties of the materials. Previous researches mostly concentrated on the effect of SFT on the mechanical response of material under quasi-static or constant strain rate loading condition, while very few studies focused on its influence on mechanical properties under the shock loading condition. Spallation is a typical failure mode of ductile metal material under shock loading, and the initial defects in the material have a great influence on the spallation behavior. In this study, molecular dynamics simulation is carried out to investigate the influence of SFT on spallation behavior of irradiated copper single crystal under different shock intensities. Copper single crystal with a perfect structural model is also investigated under the same simulation condition for comparison. The model is divided into two parts: the flyer and the target. The shock wave is generated by moving the flyer at a velocity in a range of 1.0–2.5 km/s along the [111] crystallographic orientation to achieve the desired shock-state particle velocity Up in a range of 0.5–1.25 km/s. The time evolution of pressure, free surface velocity and corresponding microstructure, are analyzed in detail to illuminate the spallation behavior of the Cu with SFT. It is revealed that the SFT collapses during shock compression and induces the generation of dislocations and stacking faults in the material. Subsequently, spallation happens when the voids nucleate and grow in the region of dislocations and stacking faults. Moreover, the materials show different spallation behaviors at different shock intensities. When Up ≤ 1.0 km/s, only elastic deformation occurs in perfect single crystal copper under shock compression, but in the copper with SFT, local defects appear and plastic deformation occurs due to the collapse of SFT under shock compression. The influence of SFT on spallation is most pronounced at a medium shock intensity. When Up = 0.75 km/s, the local defects caused by the collapse of SFT provide a wider nucleation area for the voids and promote the heterogeneous nucleation of the voids, resulting in the decreasing of the spall strength. The void nucleation of single crystal copper with SFT is found to be much later than the perfect one and the rate of spall damage evolution also decreases due to energy dissipation during SFT’s collapse and plastic deformation. When Up increases to 1.25 km/s, shock compression induces many defected atoms in both samples, so the SFT has little influence on the spall strength and spall damage of the materials.
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Keywords:
- spallation /
- stacking fault tetrahedron /
- shock /
- molecular dynamics
[1] Zinkle S J, Busby J T 2009 Mater. Today 12 12
[2] Yoshida N, Akashi Y, Kitajima K, Kiritani M 1985 J. Nucl. Mater. 133 405
[3] Zinkle S J, Farrell K 1989 J. Nucl. Mater. 168 262Google Scholar
[4] Hashimoto N, Byun T S, Farrell K 2006 J. Nucl. Mater. 351 295Google Scholar
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[6] Fabritsiev S A, Pokrovsky A S 2007 J. Nucl. Mater. 367 977
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[9] Lin E Q, Shi H, Niu L 2014 Modell. Simul. Mater. Sci. Eng. 22 035012Google Scholar
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[11] Dai Y, Victoria M 1996 MRS. Symp. Proc. 439 319
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[14] Osetsky Y N, Stoller R E, Rodney D, Bacon D J 2005 Mater. Sci. Eng., A 400 370
[15] Osetsky Y N, Rodney D, Bacon D J 2006 Philos. Mag. 86 2295Google Scholar
[16] Fan H, El-Awady J A, Wang Q 2015 J. Nucl. Mater. 458 176Google Scholar
[17] Fan H, Wang Q, Ouyang C 2015 J. Nucl. Mater. 465 245Google Scholar
[18] Martínez E, Uberuaga B P, Beyerlein I J 2016 Phys. Rev. B 93 054105Google Scholar
[19] Arsenlis A, Wirth B D, Rhee M 2004 Philos. Mag. 84 3617Google Scholar
[20] Krishna S, Zamiri A, De S 2010 Philos. Mag. 90 4013Google Scholar
[21] Xiao X Z, Song D K, Xue J M, Chu H J, Duan H L 2015 Int. J. Plast. 65 152Google Scholar
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[25] Xiao X Z, Song D K, Chu H J, Xue J M, Duan H L 2015 Int. J. Plast. 74 110Google Scholar
[26] Salehinia I, Bahr D F 2012 Scr. Mater. 66 339Google Scholar
[27] Figueroa E, Tramontina D, Gutierrez G, Bringa E 2015 J. Nucl. Mater. 467 677Google Scholar
[28] Salehinia I, Lawrence S K, Bahr D F 2013 Acta Mater. 61 1421Google Scholar
[29] Zhang L, Lu C, Tieu K, Su L, Zhao X, Pei L 2017 Mater. Sci. Eng., A 680 27Google Scholar
[30] Mishin Y, Mehl M J, Papaconstantopoulos D A, Voter A F, Kress J D 2001 Phys. Rev. B 63 224106Google Scholar
[31] Silcox J, Hirsch P B 1959 Philos. Mag. 4 1356Google Scholar
[32] Thompson A P, Plimpton S J, Mattson W 2009 J. Chem. Phys. 131 154107Google Scholar
[33] Stukowski A 2010 Modell. Simul. Mater. Sci. Eng. 18 015012
[34] Stukowski A 2012 Modell. Simul. Mater. Sci. Eng. 20 045021Google Scholar
[35] Stukowski A, Albe K 2010 Modell. Simul. Mater. Sci. Eng. 18 085001Google Scholar
[36] Luo S N, Qi A, Germann T C, Han L B 2009 J. Appl. Phys. 106 013502Google Scholar
[37] 裴晓阳, 彭辉, 贺红亮, 李平 2015 物理学报 64 034601Google Scholar
Pei X Y, Peng H, He H L, Li P 2015 Acta Phys. Sin. 64 034601Google Scholar
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图 4 压缩过程中SFT的演化形态图及对应的位错演化图(其中, 玫红色线是压杆位错, 绿色线是Shockley不完全位错, 浅蓝色线是Frank不完全位错, 红色线是其他位错) (a) Up = 0.5 km/s; (b) Up = 0.75 km/s
Figure 4. Snapshots of SFT configuration and dislocation evolution at different deformation stages during shock compression: (a) Up = 0.5 km/s; (b) Up = 0.75 km/s. The rose red line represents the stair-rod dislocation, the green line represents the Shockley partial dislocation, the light blue line represents the Frank partial dislocation, and the red line is the undefined dislocation.
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[1] Zinkle S J, Busby J T 2009 Mater. Today 12 12
[2] Yoshida N, Akashi Y, Kitajima K, Kiritani M 1985 J. Nucl. Mater. 133 405
[3] Zinkle S J, Farrell K 1989 J. Nucl. Mater. 168 262Google Scholar
[4] Hashimoto N, Byun T S, Farrell K 2006 J. Nucl. Mater. 351 295Google Scholar
[5] Schäublin R, Yao Z, Baluc N, Victoria M 2005 Philos. Mag. 85 769Google Scholar
[6] Fabritsiev S A, Pokrovsky A S 2007 J. Nucl. Mater. 367 977
[7] Shao J L, Wang P, He A M, Duan S Q, Qin C S 2014 Modell. Simul. Mater. Sci. Eng. 22 025012Google Scholar
[8] Zhou T T, He A M, Wang P, Shao J L 2019 Comput. Mater. Sci. 162 255Google Scholar
[9] Lin E Q, Shi H, Niu L 2014 Modell. Simul. Mater. Sci. Eng. 22 035012Google Scholar
[10] Qiu T, Xiong Y N, Xiao S F, Li X F, Hu W Y, Deng H Q 2017 Comput. Mater. Sci. 137 273Google Scholar
[11] Dai Y, Victoria M 1996 MRS. Symp. Proc. 439 319
[12] Edwards D J, Singh B N, Bilde-Sørensen J B 2005 J. Nucl. Mater. 342 164Google Scholar
[13] Lee H J, Wirth B D 2009 Philos. Mag. 89 821Google Scholar
[14] Osetsky Y N, Stoller R E, Rodney D, Bacon D J 2005 Mater. Sci. Eng., A 400 370
[15] Osetsky Y N, Rodney D, Bacon D J 2006 Philos. Mag. 86 2295Google Scholar
[16] Fan H, El-Awady J A, Wang Q 2015 J. Nucl. Mater. 458 176Google Scholar
[17] Fan H, Wang Q, Ouyang C 2015 J. Nucl. Mater. 465 245Google Scholar
[18] Martínez E, Uberuaga B P, Beyerlein I J 2016 Phys. Rev. B 93 054105Google Scholar
[19] Arsenlis A, Wirth B D, Rhee M 2004 Philos. Mag. 84 3617Google Scholar
[20] Krishna S, Zamiri A, De S 2010 Philos. Mag. 90 4013Google Scholar
[21] Xiao X Z, Song D K, Xue J M, Chu H J, Duan H L 2015 Int. J. Plast. 65 152Google Scholar
[22] Zhang L, Lu C, Tieu K, Shibuta Y 2018 Scr. Mater. 144 78Google Scholar
[23] Wu L P, Yu W S, Hu S L, Shen S P 2017 Int. J. Plast. 97 246Google Scholar
[24] Wu L P, Yu W S, Hu S L, Shen S P 2018 Comput. Mater. Sci. 155 256Google Scholar
[25] Xiao X Z, Song D K, Chu H J, Xue J M, Duan H L 2015 Int. J. Plast. 74 110Google Scholar
[26] Salehinia I, Bahr D F 2012 Scr. Mater. 66 339Google Scholar
[27] Figueroa E, Tramontina D, Gutierrez G, Bringa E 2015 J. Nucl. Mater. 467 677Google Scholar
[28] Salehinia I, Lawrence S K, Bahr D F 2013 Acta Mater. 61 1421Google Scholar
[29] Zhang L, Lu C, Tieu K, Su L, Zhao X, Pei L 2017 Mater. Sci. Eng., A 680 27Google Scholar
[30] Mishin Y, Mehl M J, Papaconstantopoulos D A, Voter A F, Kress J D 2001 Phys. Rev. B 63 224106Google Scholar
[31] Silcox J, Hirsch P B 1959 Philos. Mag. 4 1356Google Scholar
[32] Thompson A P, Plimpton S J, Mattson W 2009 J. Chem. Phys. 131 154107Google Scholar
[33] Stukowski A 2010 Modell. Simul. Mater. Sci. Eng. 18 015012
[34] Stukowski A 2012 Modell. Simul. Mater. Sci. Eng. 20 045021Google Scholar
[35] Stukowski A, Albe K 2010 Modell. Simul. Mater. Sci. Eng. 18 085001Google Scholar
[36] Luo S N, Qi A, Germann T C, Han L B 2009 J. Appl. Phys. 106 013502Google Scholar
[37] 裴晓阳, 彭辉, 贺红亮, 李平 2015 物理学报 64 034601Google Scholar
Pei X Y, Peng H, He H L, Li P 2015 Acta Phys. Sin. 64 034601Google Scholar
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