|
|
Research Progress on the Interface Design and Interface Response of Irradiation Resistant Metal-Based Nanostructured Materials |
LIU Yue1(), TANG Pengzheng1, YANG Kunming1, SHEN Yiming2, WU Zhongguang2, FAN Tongxiang1() |
1.State Key Laboratory of Metal Matrix Composites, Shanghai Jiao Tong University, Shanghai 200240, China 2.Shanghai Academy of Spaceflight Technology, Shanghai 201109, China |
|
Cite this article:
LIU Yue, TANG Pengzheng, YANG Kunming, SHEN Yiming, WU Zhongguang, FAN Tongxiang. Research Progress on the Interface Design and Interface Response of Irradiation Resistant Metal-Based Nanostructured Materials. Acta Metall Sin, 2021, 57(2): 150-170.
|
Abstract High-energy particle irradiation can often cause microstructure damage, resulting in different types of defects in metal-based structured materials. These irradiation-induced defects can accumulate and evolve, leading to the deformation and reduction of the structural integrity of the materials. Finally, this causes the degradation of the mechanical and physical properties of the aforementioned materials. These defects can be shielded, absorbed, and annihilated by introducing interfaces in materials, alleviating the radiation damage. In the previous two decades, metal-based nanostructured materials have attracted considerable attention in designing irradiation-resistant materials because of its high density of internal interfaces. This review aims to investigate the effect of the interface microstructure and energy on strengthening the irradiation resistance of metal-based nanostructured materials, with special emphasis on the interface responses of low- and high-energy interfaces. Furthermore, this review provides the theoretical and scientific foundation for optimizing the interface structure design and exhibits delicate balance between the interface microstructure, interface energy, interface stability, and irradiation resistance. In addition, the recent research progress on irradiation-resistant carbon-/metal-based nanostructured materials that consider such interface characteristics is reviewed in detail. Finally, the prospect of future irradiation-resistant metal-based nanostructured material development is discussed.
|
Received: 21 May 2020
|
|
Fund: National Natural Science Foundation of China(51901129);National Key Research and Development Program of China(2017YFB0703101) |
1 |
Zinkle S J, Was G S. Materials challenges in nuclear energy [J]. Acta Mater., 2013, 61: 735
|
2 |
Chu S, Majumdar A. Opportunities and challenges for a sustainable energy future [J]. Nature, 2012, 488: 294
|
3 |
Zinkle S J, Busby J T. Structural materials for fission & fusion energy [J]. Mater. Today, 2009, 12: 12
|
4 |
Odette G R, Alinger M J, Wirth B D. Recent developments in irradiation-resistant steels [J]. Annu. Rev. Mater. Res., 2008, 38: 471
|
5 |
Was G S. Fundamentals of Radiation Materials Science: Metals and Alloys [M]. New York: Springer, 2007: 827
|
6 |
Zinkle S J, Snead L L. Designing radiation resistance in materials for fusion energy [J]. Annu. Rev. Mater. Res., 2014, 44: 241
|
7 |
Odette G R, Alinger M J, Wirth B D. Recent developments in irradiation-resistant steels [J]. Annu. Rev. Mater. Res., 2008, 38: 471
|
8 |
Bai X M, Voter A F, Hoagland R G, et al. Efficient annealing of radiation damage near grain boundaries via interstitial emission [J]. Science, 2010, 327: 1631
|
9 |
Cheng G M, Xu W Z, Wang Y Q, et al. Grain size effect on radiation tolerance of nanocrystalline Mo [J]. Scr. Mater., 2016, 123: 90
|
10 |
Yu K Y, Sun C, Chen Y, et al. Superior tolerance of Ag/Ni multilayers against Kr ion irradiation: An in situ study [J]. Philos. Mag., 2013, 93: 3547
|
11 |
Han W Z, Demkowicz M J, Mara N A, et al. Design of radiation tolerant materials via interface engineering [J]. Adv. Mater., 2013, 25: 6975
|
12 |
Fu E G, Caro M, Zepeda-Ruiz L A, et al. Surface effects on the radiation response of nanoporous Au foams [J]. Appl. Phys. Lett., 2012, 101: 191607
|
13 |
Han W Z, Demkowicz M J, Fu E G, et al. Effect of grain boundary character on sink efficiency [J]. Acta Mater., 2012, 60: 6341
|
14 |
Gao J, Liu Z J, Wan F R. Limited effect of twin boundaries on radiation damage [J]. Acta Metall. Sin. (Engl. Lett.), 2016, 29: 72
|
15 |
Mao S M, Shu S P, Zhou J, et al. Quantitative comparison of sink efficiency of Cu-Nb, Cu-V and Cu-Ni interfaces for point defects [J]. Acta Mater., 2015, 82: 328
|
16 |
Vattré A J, Abdolrahim N, Kolluri K, et al. Computational design of patterned interfaces using reduced order models [J]. Sci. Rep., 2014, 4: 6231
|
17 |
Beyerlein I J, Demkowicz M J, Misra A, et al. Defect-interface interactions [J]. Prog. Mater. Sci., 2015, 74: 125
|
18 |
Vetterick G A, Gruber J, Suri P K, et al. Achieving radiation tolerance through non-equilibrium grain boundary structures [J]. Sci. Rep., 2017, 7: 12275
|
19 |
Qin W J, Ren F, Doerner R P, et al. Nanochannel structures in W enhance radiation tolerance [J]. Acta Mater., 2018, 153: 147
|
20 |
Fan C, Li J, Fan Z, et al. In situ studies on the irradiation-induced twin boundary-defect interactions in Cu [J]. Metall. Mater. Trans., 2017, 48A: 5172
|
21 |
Tang X Z, Guo Y F, Fan Y, et al. Interstitial emission at grain boundary in nanolayered alpha-Fe [J]. Acta Mater., 2016, 105: 147
|
22 |
Bufford D, Wang H, Zhang X. High strength, epitaxial nanotwinned Ag films [J]. Acta Mater., 2011, 59: 93
|
23 |
Hodge A M, Furnish T A, Shute C J, et al. Twin stability in highly nanotwinned Cu under compression, torsion and tension [J]. Scr. Mater., 2012, 66: 872
|
24 |
Demkowicz M J, Anderoglu O, Zhang X H, et al. The influence of ∑3 twin boundaries on the formation of radiation-induced defect clusters in nanotwinned Cu [J]. J. Mater. Res., 2011, 26: 1666
|
25 |
Yu K Y, Bufford D, Sun C, et al. Removal of stacking-fault tetrahedra by twin boundaries in nanotwinned metals [J]. Nat. Commun., 2013, 4: 1377
|
26 |
Li J, Yu K Y, Chen Y, et al. In situ study of defect migration kinetics and self-healing of twin boundaries in heavy ion irradiated nanotwinned metals [J]. Nano Lett., 2015, 15: 2922
|
27 |
Wang Y M, Sansoz F, Lagrange T, et al. Defective twin boundaries in nanotwinned metals [J]. Nat. Mater., 2013, 12: 697
|
28 |
Jiao S Y, Kulkarni Y. Radiation tolerance of nanotwinned metals—An atomistic perspective [J]. Comp. Mater. Sci., 2018, 142: 290
|
29 |
Jin Z H, Gumbsch P, Albe K, et al. Interactions between non-screw lattice dislocations and coherent twin boundaries in face-centered cubic metals [J]. Acta Mater., 2008, 56: 1126
|
30 |
Wang J, Huang H. Novel deformation mechanism of twinned nanowires [J]. Appl. Phys. Lett., 2006, 88: 203112.
|
31 |
Li N, Wang J, Misra A, et al. Twinning dislocation multiplication at a coherent twin boundary [J]. Acta Mater., 2011, 59: 5989
|
32 |
Chen Y X, Fu E G, Yu K Y, et al. Enhanced radiation tolerance in immiscible Cu/Fe multilayers with coherent and incoherent layer interfaces [J]. J. Mater. Res., 2015, 30: 1300
|
33 |
Fu E G, Misra A, Wang H, et al. Interface enabled defects reduction in helium ion irradiated Cu/V nanolayers [J]. J. Nucl. Mater., 2010, 407: 178
|
34 |
Chen Y, Liu Y, Fu E G, et al. Unusual size-dependent strengthening mechanisms in helium ion-irradiated immiscible coherent Cu/Co nanolayers [J]. Acta Mater., 2015, 84: 393
|
35 |
Heinisch H L, Gao F, Kurtz R J. The effects of interfaces on radiation damage production in layered metal composites [J]. J. Nucl. Mater., 2004, 329-333: 924
|
36 |
Wang J, Misra A, Hirth J P. Shear response of 3 {112} twin boundaries in face-centered-cubic metals [J]. Phys. Rev., 2011, 83B: 064106
|
37 |
Yu K Y, Bufford D, Khatkhatay F, et al. In situ studies of irradiation-induced twin boundary migration in nanotwinned Ag [J]. Scr. Mater., 2013, 69: 385
|
38 |
Chen Y, Yu K Y, Liu Y, et al. Damage-tolerant nanotwinned metals with nanovoids under radiation environments [J]. Nat. Commun., 2015, 6: 7036
|
39 |
Li N, Wang J, Wang Y Q, et al. Incoherent twin boundary migration induced by ion irradiation in Cu [J]. J. Appl. Phys., 2013, 113: 023508
|
40 |
Borovikov V, Mendelev M I, King A H. Effects of solutes on the thermal stability of nanotwinned materials [J]. Philos. Mag., 2014, 94: 2875
|
41 |
Zhu H Y, Liu S, Liu Z R, et al. Tailoring the stability of {101¯2} twins in magnesium with solute segregation at the twin boundary and strain path control [J]. Comp. Mater. Sci., 2018, 152: 113
|
42 |
Fan C C, Xie D Y, Li J, et al. 9R phase enabled superior radiation stability of nanotwinned Cu alloys via in situ radiation at elevated temperature [J]. Acta Mater., 2019, 167: 248
|
43 |
Li J, Xie D Y, Xue S, et al. Superior twin stability and radiation resistance of nanotwinned Ag solid solution alloy [J]. Acta Mater., 2018, 151: 395
|
44 |
Tschopp M A, Solanki K N, Gao F, et al. Probing grain boundary sink strength at the nanoscale: Energetics and length scales of vacancy and interstitial absorption by grain boundaries in α-Fe [J]. Phys. Rev., 2012, 85B: 064108
|
45 |
Barr C M, Barnard L, Nathaniel J E, et al. Grain boundary character dependence of radiation-induced segregation in a model Ni-Cr alloy [J]. J. Mater. Res., 2015, 30: 1290
|
46 |
Jiang C, Swaminathan N, Deng J, et al. Effect of grain boundary stresses on sink strength [J]. Mater. Res. Lett., 2014, 2: 100
|
47 |
El-Atwani O, Nathaniel J E, Leff A C, et al. The role of grain size in He bubble formation: Implications for swelling resistance [J]. J. Nucl. Mater., 2017, 484: 236
|
48 |
Sun C, Zheng S, Wei C C, et al. Superior radiation-resistant nanoengineered austenitic 304L stainless steel for applications in extreme radiation environments [J]. Sci. Rep., 2015, 5: 7801
|
49 |
Samaras M, Derlet P M, Van Swygenhoven H, et al. Radiation damage near grain boundaries [J]. Philos. Mag., 2003, 83: 3599
|
50 |
Xu J, Liu J B, Li S N, et al. Self-healing properties of nanocrystalline materials: A first-principles analysis of the role of grain boundaries [J]. Phys. Chem. Chem. Phys., 2016, 18: 17930
|
51 |
Sun C, Song M, Yu K Y, et al. In situ evidence of defect cluster absorption by grain boundaries in Kr ion irradiated nanocrystalline Ni [J]. Metall. Mater. Trans., 2013, 44A: 1966
|
52 |
Liu L L, Tang Z, Xiao W, et al. Self-healing mechanism of irradiation defects near Σ=11(113) grain boundary in copper [J]. Mater. Lett., 2013, 109: 221
|
53 |
Di C, Wang J, Chen T Y, et al. Defect annihilation at grain boundaries in alpha-Fe [J]. Sci. Rep., 2013, 3: 1450
|
54 |
Kirchheim R. Grain coarsening inhibited by solute segregation [J]. Acta Mater., 2002, 50: 413
|
55 |
Koch C C, Scattergood R O, Darling K A, et al. Stabilization of nanocrystalline grain sizes by solute additions [J]. J. Mater. Sci., 2008, 43: 7264
|
56 |
Liu F, Kirchheim R. Nano-scale grain growth inhibited by reducing grain boundary energy through solute segregation [J]. J. Cryst. Growth, 2004, 264: 385
|
57 |
Darling K A, Kecskes L J, Atwater M, et al. Thermal stability of nanocrystalline nickel with yttrium additions [J]. J. Mater. Res., 2013, 28: 1813
|
58 |
Du C C, Jin S B, Fang Y, et al. Ultrastrong nanocrystalline steel with exceptional thermal stability and radiation tolerance [J]. Nat. Commun., 2018, 9: 5389
|
59 |
Fang Y, Ge W, Yang T F, et al. Radiation tolerance of La-doped nanocrystalline steel under heavy-ion irradiation at different temperatures [J]. Nanotechnology, 2018, 29: 494001
|
60 |
El-Atwani O, Li N, Li M, et al. Outstanding radiation resistance of tungsten-based high-entropy alloys [J]. Sci. Adv., 2019, 5: eaav2002
|
61 |
Barnes R S, Redding G B, Cottrbll A H. The observation of vacancy sources in metals [J]. Philos. Mag., 1958, 3A: 97
|
62 |
Chen D, Li N, Yuryev D, et al. Imaging the in-plane distribution of helium precipitates at a Cu/V interface [J]. Mater. Res. Lett., 2017, 5: 335
|
63 |
Misra A, Demkowicz M J, Zhang X, et al. The radiation damage tolerance of ultra-high strength nanolayered composites [J]. JOM, 2007, 59(9): 62
|
64 |
Demkowicz M J, Hoagland R G, Hirth J P. Interface structure and radiation damage resistance in Cu-Nb multilayer nanocomposites [J]. Phys. Rev. Lett., 2008, 100: 136102
|
65 |
Shao S, Wang J, Misra A, et al. Spiral patterns of dislocations at nodes in (111) semi-coherent FCC interfaces [J]. Sci. Rep., 2013, 3: 2448
|
66 |
Vattré A J, Demkowicz M J. Determining the Burgers vectors and elastic strain energies of interface dislocation arrays using anisotropic elasticity theory [J]. Acta Mater., 2013, 61: 5172
|
67 |
Hirth J P, Pond R C, Hoagland R G, et al. Interface defects, reference spaces and the Frank-Bilby equation [J]. Prog. Mater. Sci., 2013, 58: 749
|
68 |
Vattré A, Jourdan T, Ding H, et al. Non-random walk diffusion enhances the sink strength of semicoherent interfaces [J]. Nat. Commun., 2016, 7: 10424
|
69 |
Reed D J. A review of recent theoretical developments in the understanding of the migration of helium in metals and its interaction with lattice defects [J]. Rad. Eff., 1977, 31: 129
|
70 |
McPhie M G, Capolungo L, Dunn A Y, et al. Interfacial trapping mechanism of He in Cu-Nb multilayer materials [J]. J. Nucl. Mater., 2013, 437: 222
|
71 |
Höchbauer T, Misra A, Hattar K, et al. Influence of interfaces on the storage of ion-implanted He in multilayered metallic composites [J]. J. Appl. Phys., 2005, 98: 123516
|
72 |
Lach T G, Ekiz E H, Averback R S, et al. Role of interfaces on the trapping of He in 2D and 3D Cu-Nb nanocomposites [J]. J. Nucl. Mater., 2015, 466: 36
|
73 |
Demkowicz M J, Bhattacharyya D, Usov I, et al. The effect of excess atomic volume on He bubble formation at fcc-bcc interfaces [J]. Appl. Phys. Lett., 2010, 97: 161903
|
74 |
Demkowicz M J, Misra A, Caro A. The role of interface structure in controlling high helium concentrations [J]. Curr. Opin. Solid State Mater. Sci., 2012, 16: 101
|
75 |
Bollmann W. O-lattice calculation of an F.C.C.-B.C.C. interface [J]. Phys. Status Solidi, 1974, 21A: 543
|
76 |
Yuryev D V, Demkowicz M J. Computational design of solid-state interfaces using O-lattice theory: An application to mitigating helium-induced damage [J]. Appl. Phys. Lett., 2014, 105: 221601
|
77 |
Yang L X, Zheng S J, Zhou Y T, et al. Effects of He radiation on cavity distribution and hardness of bulk nanolayered Cu-Nb composites [J]. J. Nucl. Mater., 2017, 487: 311
|
78 |
Chen D, Li N, Yuryev D, et al. Self-organization of helium precipitates into elongated channels within metal nanolayers [J]. Sci. Adv., 2017, 3: eaao2710
|
79 |
So K P, Chen D, Kushima A, et al. Dispersion of carbon nanotubes in aluminum improves radiation resistance [J]. Nano Energy, 2016, 22: 319
|
80 |
Wang X S, Li Q Q, Xie J, et al. Fabrication of ultralong and electrically uniform single-walled carbon nanotubes on clean substrates [J]. Nano Lett., 2009, 9: 3137
|
81 |
González R I, Valencia F, Mella J, et al. Metal-nanotube composites as radiation resistant materials [J]. Appl. Phys. Lett., 2016, 109: 033108
|
82 |
Si S Y, Li W Q, Zhao X L, et al. Significant radiation tolerance and moderate reduction in thermal transport of a tungsten nanofilm by inserting monolayer graphene [J]. Adv. Mater., 2017, 29: 1604623
|
83 |
Kim Y, Baek J, Kim S, et al. Radiation resistant vanadium-graphene nanolayered composite [J]. Sci. Rep., 2016, 6: 24785
|
84 |
Huang H, Tang X B, Chen F D, et al. Radiation damage resistance and interface stability of copper-graphene nanolayered composite [J]. J. Nucl. Mater., 2015, 460: 16
|
85 |
Yang T L, Yang L, Liu H, et al. Ab initio study of stability and migration of point defects in copper-graphene layered composite [J]. J. Alloys Compd., 2017, 692: 49
|
86 |
Huang H, Tang X B, Chen F D, et al. Graphene damage effects on radiation-resistance and configuration of copper-graphene nanocomposite under irradiation: A molecular dynamics study [J]. Sci. Rep., 2016, 6: 39391
|
No Suggested Reading articles found! |
|
|
Viewed |
|
|
|
Full text
|
|
|
|
|
Abstract
|
|
|
|
|
Cited |
|
|
|
|
|
Shared |
|
|
|
|
|
Discussed |
|
|
|
|