Effect of dislocation on helium irradiation defects in low-activation martensitic steel

Dong Ye; Zhu Te; Song Ya-Min; Ye Feng-Jiao; Zhang Peng; Yang Qi-Gui; Liu Fu-Yan; Chen Yu; Cao Xing-Zhong

doi:10.7498/aps.72.20230694

Abstract

Reduced-activation martensitic steel is a main candidate structural material for key components of advanced nuclear energy systems because of its good mechanical properties at room temperature, low neutron activation characteristics and satisfactory radiation resistance. In this work, we study the interaction between dislocations and helium-irradiation-induced defects in the steel and the effect of dislocations on the behavior of helium migration and desorption. The well-annealed samples are pre-deformed to 10% and 20% reductions in thickness by using cold rolling mill. After pre-deformation, samples are heat-treated to remove vacancy defects and retain dislocation defects. Then, the samples with reserved dislocations are irradiated with helium at room temperature (50 keV, 1×10¹⁷ He/cm²). After irradiation, the samples are characterized by synchrotron radiation grazing incident X-Ray diffraction, positron annihilation Doppler broadening spectroscopy, and thermal desorption spectroscopy. The results show that dislocations hinder the diffusion of helium and helium-vacancy complexes, and reduce the accumulation of radiation damage. Such an effect becomes more significant with the increase of dislocation density. The BCC → FCC phase transition of low activation martensitic steel occurs at 1179 K. The increase of dislocation density will lead to the forward shift of helium desorption peak induced by phase transition. The retention of helium in the undeformed sample, 10% deformed sample and 20% deformed sample is 10.3%, 15.7% and 17.9%, respectively, indicating that high density dislocations promote the retention of helium.

Keywords:

Authors and contacts

1.
Institute of High Energy Physics, Chinese Academy of Sciences, Beijing 100049, China
2.
University of Chinese Academy of Sciences, Beijing 100039, China

Corresponding author: Cao Xing-Zhong, caoxzh@ihep.ac.cn

Funds: Project supported by the National Key R&D Program of China (Grant No. 2019YFA0210002) and the National Natural Science Foundation of China (Grant Nos. U1732265, 11775235, 12175262, 12005229).

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References

[1]	Baluc N, Abe K, Boutard J L, Chernov V M, Diegele E, Jitsukawa S, Kimura A, Klueh R L, Kohyama A, Kurtz R J, Lässer R, Matsui H, Möslang A, Muroga T, Odette G R, Tran M Q, van der Schaaf B, Wu Y, Yu J, Zinkle S J 2007 Nucl. Fusion 47 S696 Google Scholar
[2]	Kurtz R J, Alamo A, Lucon E, Huang Q, Jitsukawa S, Kimura A, Klueh R L, Odette G R, Petersen C, Sokolov M A, Spätig P, Rensman J W 2009 J. Nucl. Mater. 386−388 411 Google Scholar
[3]	Huang Q 2014 J. Nucl. Mater. 455 649 Google Scholar
[4]	Niwase K, Ezawa T, Tanabe T, Kiritani M, Fujita F E 1993 J. Nucl. Mater. 203 56 Google Scholar
[5]	Mansur L K, Coghlan W A 1983 J. Nucl. Mater. 119 1 Google Scholar
[6]	Chernov I I, Kalashnikov A N, Kalin B A, Binyukova S Y 2003 J. Nucl. Mater. 323 341 Google Scholar
[7]	Xu Q, Sugiura Y, Pan X Q, Sato K, Yoshiie T 2014 Mat. Sci. Eng. A-Struct. 612 41 Google Scholar
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[11]	van den Beukel A 2014 Chin. Phys. Lett. 31 036101 Google Scholar
[12]	Sarkar D K, Bera S, Narasimhan S V, Chowdhury S, Gupta A, Nair K G M 1998 Solid State Commun. 107 413 Google Scholar
[13]	Zhu T, Zhong Z H, Sato K, Song Y M, Ye F J, Wang Q Q, Dong Y, Zhang P, Yu R S, Wang B Y, Ngan A H W, Cao X Z, Xu Q 2022 Tungsten 4 212 Google Scholar
[14]	Zhang Z, Zhu T, Jin S, Zhang P, Kuang P, Guo L P, An X, Wang B Y, Yu R, Zhang S, Cao X Z 2020 Fusion Eng. Des. 161 111978 Google Scholar
[15]	Zhu T, Jin S, Gong Y, Lu E Y, Song L G, Xu Q, Guo L P, Cao X Z, Wang B Y 2017 J. Nucl. Mater. 495 244 Google Scholar
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[18]	Jin S X, Zhang P, Lu E Y, Guo L P, Wang B Y, Cao X Z 2016 Acta Mater. 103 658 Google Scholar
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[22]	Zhang S, Cizek J, Yao Z, Oleksandr M, Kong X, Liu C, van Dijk N, van der Zwaag S 2020 J. Alloys Compd. 817 152765 Google Scholar
[23]	Morishita K, Sugano R, Wirth B D 2003 J. Nucl. Mater. 323 243 Google Scholar
[24]	Xu D, Bus T, Glade S C, Wirth B D 2007 J. Nucl. Mater. 367 483 Google Scholar
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图 1 低活化马氏体钢的TEM图　(a) 1013 K退火; (b) 10%变形; (c) 20%变形. 在1013 K退火后的样品中观察到少量缺陷, 将退火样品冷轧变形10%和20%发现大量位错

Figure 1. (a) TEM micrographs of the well-annealed sample, a small number of defects are observed. (b), (c) The image of the annealed specimens after cold-worked, a number of dislocations induced by cold rolling to 10% (b) and 20% (c) of their original thickness are observed.

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图 2 50 keV氦离子辐照低活化马氏体钢的辐照损伤以及氦原子深度分布的SRIM模拟(dpa, 原子平均离位; appm, 原子性部分每百万)

Figure 2. Depth distribution of vacancies and helium atoms in 50 keV helium-ion irradiated low activation martensitic steel, calculated with SRIM 2013 (dpa, displacement per atom; appm, atomic parts per million).

DownLoad: Full-Size Img PowerPoint

图 3 不同形变辐照条件下低活化马氏体钢的GIXRD谱图

Figure 3. GIXRD patterns of low activation martensitic steel with different conditions.

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图 4 50 keV的氦辐照低活化马氏体钢的多普勒展宽谱　(a) S-E曲线; (b) W-E曲线; (c) S-W曲线

Figure 4. Doppler broadening spectrum of low activation martensitic steel irradiated with 50 keV ion helium: (a) S-E curves, (b) W-E curves; (c) S-W curves.

DownLoad: Full-Size Img PowerPoint

图 5 50 keV的氦辐照低活化马氏体钢的多普勒展宽谱　(a) ΔS-E曲线; (b) ΔW-E线

Figure 5. Doppler broadening spectrum of low activation martensitic steel irradiated with 50 keV ion helium: (a) ΔS-E curves; (b) ΔW-E curves.

DownLoad: Full-Size Img PowerPoint

图 6 低活化马氏体钢的热脱附谱图

Figure 6. Helium thermal desorption spectra for low activation martensitic steel.

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表 1 低活化马氏体钢的化学成分

Table 1. Chemical composition of the low activation martensitic steel.

元素	Cr	V	Ta	W	C	Mn	Si	P	S	Fe
质量分数/%	9.100	0.190	0.200	1.500	0.120	0.400	0.025	0.003	0.003	88.459

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表 2 同步辐射X射线衍射数据, 即不同形变辐照条件下低活化马氏体钢的2θ和FWHM

Table 2. Synchrotron radiation X-ray diffraction data, namely, 2θ and FWHM of low activation martensitic steel with different conditions.

Sample	2θ/FWHM
Sample	(110)	(200)	(211)	(220)
Undeform-unirra	44.553/0.302	64.894/0.355	82.327/0.401	98.9890/0.276
Undeform-irradiate	44.500/0.416	64.653/0.473	82.167/0.610	98.780/0.366
10%-unirra	44.566/0.359	64.902/0.466	82.330/0.583	99.008/0.355
10%-irradiate	44.524/0.465	64.801/0.544	82.127/0.663	98.554/0.397
20%-unirra	44.563/0.351	64.880/0.345	82.356/0.573	98.979/0.330
20%-irradiate	44.154/0.474	64.249/0.478	82.054/0.694	98.749/0.736

DownLoad: CSV

表 3 低活化马氏体钢氦的热脱附能

Table 3. Desorption temperature and desorption activation energy.

Peak		Temperature/K	Energy/eV
Undeformed	A2	1164	3.38
Undeformed	A3	1179	3.41
10% deformation	B1	1073	3.11
	B2	1128	3.27
	B3	1149	3.33
20% deformation	C1	1028	2.98
	C2	1096	3.18
	C3	1115	3.23

DownLoad: CSV

[1]	Baluc N, Abe K, Boutard J L, Chernov V M, Diegele E, Jitsukawa S, Kimura A, Klueh R L, Kohyama A, Kurtz R J, Lässer R, Matsui H, Möslang A, Muroga T, Odette G R, Tran M Q, van der Schaaf B, Wu Y, Yu J, Zinkle S J 2007 Nucl. Fusion 47 S696 Google Scholar
[2]	Kurtz R J, Alamo A, Lucon E, Huang Q, Jitsukawa S, Kimura A, Klueh R L, Odette G R, Petersen C, Sokolov M A, Spätig P, Rensman J W 2009 J. Nucl. Mater. 386−388 411 Google Scholar
[3]	Huang Q 2014 J. Nucl. Mater. 455 649 Google Scholar
[4]	Niwase K, Ezawa T, Tanabe T, Kiritani M, Fujita F E 1993 J. Nucl. Mater. 203 56 Google Scholar
[5]	Mansur L K, Coghlan W A 1983 J. Nucl. Mater. 119 1 Google Scholar
[6]	Chernov I I, Kalashnikov A N, Kalin B A, Binyukova S Y 2003 J. Nucl. Mater. 323 341 Google Scholar
[7]	Xu Q, Sugiura Y, Pan X Q, Sato K, Yoshiie T 2014 Mat. Sci. Eng. A-Struct. 612 41 Google Scholar
[8]	Woodford D A, Smith J P, Moteff J 1969 J. Nucl. Mater. 29 103 Google Scholar
[9]	van den Beukel A 1979 Scr. Metall. 13 83 Google Scholar
[10]	Cao Q, Ju X, Guo L P, Wang B 2014 Fusion Eng. Des. 89 1101 Google Scholar
[11]	van den Beukel A 2014 Chin. Phys. Lett. 31 036101 Google Scholar
[12]	Sarkar D K, Bera S, Narasimhan S V, Chowdhury S, Gupta A, Nair K G M 1998 Solid State Commun. 107 413 Google Scholar
[13]	Zhu T, Zhong Z H, Sato K, Song Y M, Ye F J, Wang Q Q, Dong Y, Zhang P, Yu R S, Wang B Y, Ngan A H W, Cao X Z, Xu Q 2022 Tungsten 4 212 Google Scholar
[14]	Zhang Z, Zhu T, Jin S, Zhang P, Kuang P, Guo L P, An X, Wang B Y, Yu R, Zhang S, Cao X Z 2020 Fusion Eng. Des. 161 111978 Google Scholar
[15]	Zhu T, Jin S, Gong Y, Lu E Y, Song L G, Xu Q, Guo L P, Cao X Z, Wang B Y 2017 J. Nucl. Mater. 495 244 Google Scholar
[16]	Sabelová V, Kršjak V, Kuriplach J, Petriska M, Slugeň V, Šimeg Veterníková J 2014 J. Nucl. Mater. 450 54 Google Scholar
[17]	Song Y M, Song L G, Lian X Y, Jin S X, Zhu T, Liu Y L, Zhang P, Wang B Y, Cao X Z 2023 JJAP Conference Proceedings 9 011103 Google Scholar
[18]	Jin S X, Zhang P, Lu E Y, Guo L P, Wang B Y, Cao X Z 2016 Acta Mater. 103 658 Google Scholar
[19]	King D A 1975 Surf. Sci. 47 384 Google Scholar
[20]	Lombardo S J, Bell A T 1988 Surf. Sci. 206 101 Google Scholar
[21]	Morishita K, Sugano R, Wirth B D, Diaz de la Rubia T 2003 Nucl. Instrum. Methods Phys. Res. Sect. B 202 76 Google Scholar
[22]	Zhang S, Cizek J, Yao Z, Oleksandr M, Kong X, Liu C, van Dijk N, van der Zwaag S 2020 J. Alloys Compd. 817 152765 Google Scholar
[23]	Morishita K, Sugano R, Wirth B D 2003 J. Nucl. Mater. 323 243 Google Scholar
[24]	Xu D, Bus T, Glade S C, Wirth B D 2007 J. Nucl. Mater. 367 483 Google Scholar
[25]	Zhu T, Cao X Z, Jin S X, Wu J P, Gong Y H, Lu E Y, Wang B Y, Yu R S, Wei L 2015 J. Nucl. Mater. 466 522 Google Scholar
[26]	Yonemura M, Inoue K 2016 Metall. Mater. Trans. A 47 6384 Google Scholar
[27]	Wang J R, Pan B C 2022 J. Nucl. Mater. 561 153540 Google Scholar

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