[1] Zinkle S J and Was G S 2013 Materials challenges in nuclear energy Acta Mater. 61 735–58
[2] Liu C L 2017 Development status and trend of global nuclear power Glob. Sci. Technol. Econ. Outlook 32 67–76
[3] Rong J and Liu Z 2020 Development and prospect of advanced nuclear energy technology At. Energy Sci. Technol. 54 1638–43
[4] Xu S, Chen L Z, Cao S G, Jia H D and Zhou Z J 2019 Research progress on microstructure design and control of ODS steels applied to advanced nuclear energy systems Mater. Rep. 33 78–89
[5] Wang J Q, Dai Z M and Xu H J 2019 Research status and prospect of comprehensive utilization of nuclear energy Bull. Chin. Acad. Sci. 34 460–8
[6] Hoffelner W 2010 Damage assessment in structural metallic materials for advanced nuclear plants J. Mater. Sci. 45 2247–57
[7] Murty K L and Charit I 2008 Structural materials for Gen-IV nuclear reactors: challenges and opportunities J. Nucl. Mater. 383 189–95
[8] Kurtz R J and Odette G R 2019 Overview of reactor systems and operational environments for structural materials in fusion reactors Structural Alloys for Nuclear Energy Applications ed G R Odette and S J Zinkle (Amsterdam: Elsevier) pp 51–102
[9] Yuan S W 2018 Effects of Zr and/or Ti Addition on the Nano-Scale Particles in ODS Steels as the Fuel Cladding Materials of Generation IV Nuclear Fission Reactors (Chongqing: Chongqing University)
[10] Xu Y P, Lyu Y M, Zhou H S and Luo G M 2018 A review on the development of the structural materials of the fusion blanket Mater. Rep. 32 2897–906
[11] Hirata A, Fujita T, Wen Y R, Schneibel J H, Liu C T and Chen M W 2011 Atomic structure of nanoclusters in oxide-dispersion-strengthened steels Nat. Mater. 10 922–6
[12] Zinkle S J and Snead L L 2014 Designing radiation resistance in materials for fusion energy Annu. Rev. Mater. Res. 44 241–67
[13] Zinkle S J 2013 Challenges in developing materials for fusion technology—past, present and future Fusion Sci. Technol. 64 65–75
[14] Stan T, Wu Y, Ciston J, Yamamoto T and Odette G R 2020 Characterization of polyhedral nano-oxides and helium bubbles in an annealed nanostructured ferritic alloy Acta Mater. 183 484–92
[15] Dou P, Kimura A, Okuda T, Inoue M, Ukai S, Ohnuki S, Fujisawa T and Abe F 2011 Polymorphic and coherency transition of Y–Al complex oxide particles with extrusion temperature in an Al-alloyed high-Cr oxide dispersion strengthened ferritic steel Acta Mater. 59 992–1002
[16] Zhang Z W, Yao L, Wang X-L and Miller M K 2015 Vacancy-controlled ultrastable nanoclusters in nanostructured ferritic alloys Sci. Rep. 5 10600
[17] Zinkle S J, Boutard J L, Hoelzer D T, Kimura A, Lindau R, Odette G R, Rieth M, Tan L and Tanigawa H 2017 Development of next generation tempered and ODS reduced activation ferritic/martensitic steels for fusion energy applications Nucl. Fusion 57 092005
[18] Yvon P, Le Flem M, Cabet C and Seran J L 2015 Structural materials for next generation nuclear systems: challenges and the path forward Nucl. Eng. Des. 294 161–9
[19] Ukai S and Fujiwara M 2002 Perspective of ODS alloys application in nuclear environments J. Nucl. Mater. 307–311 749–57
[20] Ukai S, Ohtsuka S, Kaito T, De Carlan Y, Ribis J and Malaplate J 2017 Oxide dispersion-strengthened/ferrite-martensite steels as core materials for generation IV nuclear reactors Structural Materials for Generation IV Nuclear Reactors ed P Yvon (Britain: Woodhead Publishing) pp 357–414
[21] Kim T K, Noh S, Kang S H, Park J J, Jin H J, Lee M K, Jang J and Rhee C K 2016 Current status and future prospective of advanced radiation resistant oxide dispersion strengthened steel (ARROS) development for nuclear reactor system applications Nucl. Eng. Technol. 48 572–94
[22] Medhat M E and Wang Y F 2015 Investigation on radiation shielding parameters of oxide dispersion strengthened steels used in high temperature nuclear reactor applications Ann. Nucl. Energy 80 365–70
[23] Laurent-Brocq M, Legendre F, Mathon M-H, Mascaro A, Poissonnet S, Radiguet B, Pareige P, Loyer M and Leseigneur O 2012 Influence of ball-milling and annealing conditions on nanocluster characteristics in oxide dispersion strengthened steels Acta Mater. 60 7150–9
[24] Xie R, Lyu Z, Lu C Y, Wang Q, Xu S H and Liu C M 2020 Effect of hot isostatic pressing temperature on microstructure and mechanical properties of 14Cr-ODS steel Mater. Rep. 34 8141–8
[25] Benjamin J S 1970 Dispersion strengthened superalloys by mechanical alloying Metall. Trans. 1 2943–51
[26] Suryanarayana C 2001 Mechanical alloying and milling Prog. Mater. Sci. 46 1–184
[27] Hary B, Logé R, Ribis J, Mathon M-H, van der Meer M, Baudin T and de Carlan Y 2018 Strain-induced dissolution of Y–Ti–O nano-oxides in a consolidated ferritic oxide dispersion strengthened (ODS) steel Materialia 4 444–8
[28] Odette G R, Cunningham N J, Stan T, Alam M E and de Carlan Y 2019 Nano-oxide dispersion-strengthened steels Structural Alloys for Nuclear Energy Applications ed G R Odette and S J Zinkle (Amsterdam: Elsevier) pp 529–83
[29] Spartacus G, Malaplate J, de Geuser F, Sornin D, Gangloff A, Guillou R and Deschamps A 2020 Nano-oxide precipitation kinetics during the consolidation process of a ferritic oxide dispersion strengthened steel. Scr. Mater. 188 10–15
[30] London A J, Santra S, Amirthapandian S, Panigrahi B K, Sarguna R M, Balaji S, Vijay R, Sundar C S, Lozano-Perez S and Grovenor C R M 2015 Effect of Ti and Cr on dispersion, structure and composition of oxide nano-particles in model ODS alloys Acta Mater. 97 223–33
[31] Verhiest K, Almazouzi A, de Wispelaere N, Petrov R and Claessens S 2009 Development of oxides dispersion strengthened steels for high temperature nuclear reactor applications J. Nucl. Mater. 385 308–11
[32] Gil E, Ord′as N, García-Rosales C and Iturriza I 2016 ODS ferritic steels produced by an alternative route (STARS): microstructural characterisation after atomisation, HIPping and heat treatments Powder Metall. 59 359–69
[33] Gil E, Cortés J, Iturriza I and Ord′as N 2018 XPS and SEM analysis of the surface of gas atomized powder precursor of ODS ferritic steels obtained through the STARS route Appl. Surf. Sci. 427 182–91
[34] Wang J Y, Wu S Z, Suo X K and Liao H L 2019 The processes for fabricating nanopowders Advanced Nanomaterials and Coatings by Thermal Spray ed G J Yang and X K Suo (Amsterdam: Elsevier) pp 13–25
[35] Dai C, Schade C, Apelian D and Lavernia E J 2018 Processing techniques for ODS stainless steels Metall. Mater. Trans. B 49 3043–55
[36] Dai C, Kurmanaeva L, Schade C, Lavernia E and Apelian D 2019 Microstructure and mechanical behavior of ODS stainless steel fabricated using cryomilling Metall. Mater. Trans. A 50 5767–81
[37] Lavernia E J, Han B Q and Schoenung J M 2008 Cryomilled nanostructured materials: processing and properties Mater. Sci. Eng. A 493 207–14
[38] Han B Q, Lavernia E J, Mohamed F A and Bampton C C 2005 Improvement of toughness and ductility of a cryomilled Al-Mg alloy via microstructural modification Metall. Mater. Trans. A 36 2081–91
[39] Sarma S S, Prasad S, Joardar J, Suresh K, Reddy A V and Vijay R 2019 Nanocrystalline ODS-iron aluminide by cryo-milling: consolidation, microstructure and mechanical behavior Mater. Res. Express 6 106572
[40] Kim Y-K, Kim J H, Kim Y-J, Seidman D N and Lee K-A 2020 Effect of milling temperatures on the microstructure and high temperature long-term oxidation resistance of oxide-dispersion strengthened steels Corros. Sci. 174 108833
[41] Gwon J-H, Kim J-H and Lee K-A 2016 Effect of cryomilling on the high temperature creep properties of oxide dispersion strengthened steels Mater. Sci. Eng. A 676 209–15
[42] Kim J H, Byun T S, Shin E, Seol J-B, Young S and Reddy N S 2015 Small angle neutron scattering analyses and high temperature mechanical properties of nano-structured oxide dispersion-strengthened steels produced via cryomilling J. Alloys Compd. 651 363–74
[43] Schneibel J H and Shim S 2008 Nano-scale oxide dispersoids by internal oxidation of Fe–Ti–Y intermetallics Mater. Sci. Eng. A 488 134–8
[44] Miran S, Franke P, M?slang A and Seifert H J 2017 Casting technology for ODS steels—the internal oxidation approach Final Limtech Coll. and Int. Symp. on Liquid Metal Technologies (Dresden: IOP) p 012021
[45] Rieken J R, Anderson I E, Kramer M J, Odette G R, Stergar E and Haney E 2012 Reactive gas atomization processing for Fe-based ODS alloys J. Nucl. Mater. 428 65–75
[46] Ord′as N, Gil E, Cintins A, de Castro V, Leguey T, Iturriza I, Purans J, Anspoks A, Kuzmin A and Kalinko A 2018 The role of yttrium and titanium during the development of ODS ferritic steels obtained through the STARS route: TEM and XAS study J. Nucl. Mater. 504 8–22
[47] Li J, Wu S J, Ma P, Yang Y, Wu E D, Xiong L Y and Liu S 2019 Microstructure evolution and mechanical properties of ODS FeCrAl alloys fabricated by an internal oxidation process Mater. Sci. Eng. A 757 42–51
[48] Li J, Wu S J, Liu S and Xiong L Y 2019 Preparation method of high-strength oxide dispersion strengthened Fe based alloy CN Patent. 109182882A
[49] Zhang Z M, Liu T T, Song B and Guo N 2020 Research on preparation of ODS ferritic stainless steel by flake powder metallurgy method and its microstructure characteristics Hot Work Technol. 49 40–44
[50] Arkhurst B M and Kim J H 2018 Evolution of microstructure and mechanical properties of oxide dispersion strengthened steels made from water-atomized ferritic powder Met. Mater. Int. 24 464–80
[51] Zhang X X, Hong Z Y, Song G, Xia M, Ge C C and Yan Q Z 2019 Research progress of ODS steels fabricated by liquid metal method Trans. Mater. Heat Treat. 40 69–84
[52] Lan J, Yang Y and Li X C 2004 Microstructure and microhardness of SiC nanoparticles reinforced magnesium composites fabricated by ultrasonic method Mater. Sci. Eng. A 386 284–90
[53] Bergner F, Hilger I, Virta J, Lagerbom J, Gerbeth G, Connolly S, Hong Z L, Grant P S and Weissg?rber T 2016 Alternative fabrication routes toward oxide-dispersion-strengthened steels and model alloys Metall. Mater. Trans. A 47 5313–24
[54] Shi Z M and Han F S 2015 The microstructure and mechanical properties of micro-scale Y2O3 strengthened 9Cr steel fabricated by vacuum casting Mater. Des. 66 304–8
[55] Shi Z M 2015 Modification of Microstructures and Properties of T91 Steel Towards ADS (Hefei: University of Science and Technology of China)
[56] Verhiest K, Mullens S, de Graeve I, de Wispelaere N, Claessens S, de Bremaecker A and Verbeken K 2014 Advances in the development of corrosion and creep resistant nano-yttria dispersed ferritic/martensitic alloys using the rapid solidification processing technique Ceram. Int. 40 14319–34
[57] Wen Y, Liu Y, Liu F, Fujita T, Liu D H, Chen M W and Huang B Y 2010 Addition of Fe2O3 as oxygen carrier for preparation of nanometer-sized oxide strengthened steels J. Nucl. Mater. 405 199–202
[58] Brocq M, Radiguet B, Le Breton J-M, Cuvilly F, Pareige P and Legendre F 2010 Nanoscale characterisation and clustering mechanism in an Fe–Y2O3 model ODS alloy processed by reactive ball milling and annealing Acta Mater. 58 1806–14
[59] Hong Z Y, Zhang X X, Yan Q Z and Chen Y X 2019 A new method for preparing 9Cr-ODS steel using elemental yttrium and Fe2O3 oxygen carrier J. Alloys Compd. 770 831–9
[60] Yan Q Z and Hong Z Y 2019 Method for preparing oxide dispersion strengthening F/M steel smelting and casting process CN Patent. 107824771B
[61] Tang H, Chen X H, Chen M W, Zuo L F, Hou B and Wang Z D 2014 Microstructure and mechanical property of in-situ nano-particle strengthened ferritic steel by novel internal oxidation Mater. Sci. Eng. A 609 293–9
[62] Grants I, R?biger D, Vogt T, Eckert S and Gerbeth G 2015 Application of magnetically driven tornado-like vortex for stirring floating particles into liquid metal Magnetohydrodynamics 51 419–24
[63] Li C J 2009 The state-of-art of research and development on cold spraying in China China Surf. Eng. 22 5–14
[64] Maier B, Lenling M, Yeom H, Johnson G, Maloy S and Sridharan K 2019 A novel approach for manufacturing oxide dispersion strengthened (ODS) steel cladding tubes using cold spray technology Nucl. Eng. Technol. 51 1069–74
[65] Deng N, Dong H, Che H Y, Li S F and Zhou Z J 2020 The research progress on preparation of metal coatings by cold spraying and its application in additive manufacturing Surf. Technol. 49 57–66
[66] Hong Z L, Morrison A P C, Zhang H T, Roberts S G and Grant P S 2018 Development of a novel melt spinning-based processing route for oxide dispersion-strengthened steels Metall. Mater. Trans. A 49 604–12
[67] Zhong Y, R?nnar L-E, Wikman S, Koptyug A, Liu L F, Cui D Q and Shen Z J 2017 Additive manufacturing of ITER first wall panel parts by two approaches: selective laser melting and electron beam melting Fusion Eng. Des. 116 24–33
[68] Walker J C, Berggreen K M, Jones A R and Sutcliffe C J 2009 Fabrication of Fe-Cr-Al oxide dispersion strengthened PM2000 alloy using selective laser melting Adv. Eng. Mater. 11 541–6
[69] Boegelein T, Dryepondt S N, Pandey A, Dawson K and Tatlock G J 2015 Mechanical response and deformation mechanisms of ferritic oxide dispersion strengthened steel structures produced by selective laser melting Acta Mater. 87 201–15
[70] Vasquez E, Giroux P-F, Lomello F, Chniouel A, Maskrot H, Schuster F and Castany P 2019 Elaboration of oxide dispersion strengthened Fe-14Cr stainless steel by selective laser melting J. Mater. Process. Technol. 267 403–13
[71] Euh K, Arkhurst B, Kim I H, Kim H-G and Kim J H 2017 Stability of Y-Ti-O nanoparticles during laser deposition of oxide dispersion strengthened steel powder Met. Mater. Int. 23 1063–74
[72] Boegelein T, Louvis E, Dawson K, Tatlock G J and Jones A R 2016 Characterisation of a complex thin walled structure fabricated by selective laser melting using a ferritic oxide dispersion strengthened steel Mater. Charact. 112 30–40
[73] Vasquez E, Giroux P-F, Lomello F, Nussbaum M, Maskrot H, Schuster F and Castany P 2020 Effect of powder characteristics on production of oxide dispersion strengthened Fe 14Cr steel by laser powder bed fusion Powder Technol. 360 998–1005
[74] Arkhurst B M, Park J J, Lee C H and Kim J H 2017 Direct laser deposition of 14Cr oxide dispersion strengthened steel powders using Y2O3 and HfO2 dispersoids Korean J. Met. Mater. 55 550–8
[75] Nguyen Q B, Nai M L S, Zhu Z G, Sun C-N, Wei J and Zhou W 2017 Characteristics of inconel powders for powder-bed additive manufacturing Engineering 3 695–700
[76] Do?ate-Buendía C et al 2018 Oxide dispersion-strengthened alloys generated by laser metal deposition of laser-generated nanoparticle-metal powder composites Mater. Des. 154 360–9
[77] Rees M, Hurst R C and Parker J D 1996 Diffusion bonding of ferritic oxide dispersion strengthened alloys to austenitic superalloys J. Mater. Sci. 31 4493–501
[78] Zhou L Y 2019 Interface Healing Mechanism of Oxide Dispersion Strengthened Steels Produced by Additive Forging (Hefei: University of Science and Technology of China)
[79] Xie B J, Sun M Y, Xu B, Wang C Y, Jiang H Y, Li D Z and Li Y Y 2019 Oxidation of stainless steel in vacuum and evolution of surface oxide scales during hot-compression bonding Corros. Sci. 147 41–52
[80] Xie B J, Sun M Y, Xu B, Wang C Y, Li D Z and Li Y Y 2018 Dissolution and evolution of interfacial oxides improving the mechanical properties of solid state bonding joints Mater. Des. 157 437–46
[81] Zhang J Y, Sun M Y, Xu B, Hu X, Liu S, Xie B J and Li D Z 2019 Evolution of the interfacial microstructure during the plastic deformation bonding of copper Mater. Sci. Eng. A 746 1–10
[82] Zhou L Y, Feng S B, Sun M Y, Xu B and Li D Z 2019 Interfacial microstructure evolution and bonding mechanisms of 14YWT alloys produced by hot compression bonding J. Mater. Sci. Technol. 35 1671–80
[83] Sun M Y, Zhao L, Li D, Xie B, Xu B, Zhang J and Li Y Y 2020 Research advances on homogenization manufacturing of heavy components by metal additive forging Chin. Sci. Bull. 61 3043–58