大塑性变形工艺制备纳米晶过饱和固溶体的研究进展<sup>*</sup>

doi:10.11896/j.issn.1005-023X.2017.021.018

Abstract
Figure/Table
References
Related Citation (15)

Download:

Full Text ( PDF ) (1775KB)
Export: BibTeX | EndNote (RIS)

Abstract Nanocrystalline supersaturated solid solution can be produced by severe plastic deformation (SPD) techniques, which exhibits the unusual microstructure and properties compared with the coarse grain materials. In recent years, the formation mechanism and thermal stability of nanocrystalline solid solutions have been extensively studied. In this paper, the progress on the preparations of the nanocrystalline supersaturated solid solutions by SPD techniques (such as mechanical alloying, high pressure torsion, etc.) is reviewed. The formation mechanisms of nanocrystalline grains and the theories of the solid solution extension are mainly discussed. The thermal stability of the nanocrystalline supersaturated solid solution is also introduced. Moreover, the method to improve the current understanding is suggested briefly.

Key words： nanocrystalline grain supersaturated solid solution severe plastic deformation thermal stability

Published: 10 November 2017 Online: 2018-05-08

CLC number:

TB383

	Service
	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	LEI Ruoshan
	CHEN Guangrun
	XU Shiqing
	WANG Huanping
	WANG Mingpu

Cite this article:

LEI Ruoshan,CHEN Guangrun,XU Shiqing, et al. Preparation of Nanocrystalline Supersaturated Solid Solution by Severe Plastic Deformation:a Review[J]. Materials Reports, 2017, 31(21): 130-134.

URL:

https://www.mater-rep.com/EN/10.11896/j.issn.1005-023X.2017.021.018 OR https://www.mater-rep.com/EN/Y2017/V31/I21/130

1 Rogachev A S, Kuskov K V, Shkodich N F, et al. Influence of high-energy ball milling on electrical resistance of Cu and Cu/Cr nanocomposite materials produced by spark plasma sintering[J]. J Alloys Compd, 2016, 688:468.
2 Dina V D, Lomovsky O I, Valeev K R. Phase evolution during early stages of mechanical alloying of Cu-13wt.% Al powder mixtures in a high-energy ball mill[J]. J Alloys Compd, 2015,629:343.
3 Aguilar C, Guzmán D, Castro F, et al. Fabrication of nanocrystalline alloys Cu-Cr-Mo supersaturate solid solution by mechanical alloying[J]. Mater Chem Phys, 2014,146:493.
4 Shen J, Chen X, Hammond V. The effect of rolling on the microstructure and compression behavior of AA5083 subjected to large-scale ECAE[J]. J Alloys Compd, 2017,695:3589.
5 Dalla T F, Lapovok R, Sandlin J, et al. Microstructure and properties of copper processed by equal channel angular extrusion for one to sixteen passes[J]. Acta Mater, 2004, 52:4819.
6 Askarpour M, Sadeghian Z, Reihanian M. Role of powder preparation route on microstructure and mechanical properties of Al-TiB₂ composites fabricated by accumulative roll bonding (ARB)[J]. Mater Sci Eng A, 2016,677:400.
7 Naseri M, Reihanian M, Borhani E. Effect of strain path on microstructure, deformation texture and mechanical properties of nano/ultrafine grained AA1050 processed by accumulative roll bonding (ARB)[J]. Mater Sci Eng A, 2016, 673:288.
8 Silva L M, Tomita J T, Bringhenti C. Numerical investigation of a HPT with different rotor tip configurations in terms of pressure ratio and efficiency[J]. Aerospace Sci Technol, 2017, 63:33.
9 Rashkova B, Faller M, Pippan R. Growth mechanism of Al₂Cu precipitates during in situ TEM heating of a HPT deformed Al-3wt.%Cu alloy[J]. J Alloys Compd, 2014,600:43.
10Darling K A, Roberts A J, Armstrong L, et al. Influence of Mn solute content on grain size reduction and improved strength in mechanically alloyed Al-Mn alloys[J]. Mater Sci Eng A, 2014, 589:57.
11Kuhnt M, Marsilius M, Strache T, et al. Magnetostriction of nanocrystalline (Fe,Co)-Si-B-P-Cu alloys[J]. Scripta Mater, 2017, 130:46.
12Parsons R, Garitaonandia J S, Yanai T, et al. Effect of Si on the field-induced anisotropy in Fe-rich nanocrystalline soft magnetic alloys[J]. J Alloys Compd, 2017,695:3156.
13Tao J M, Zhu X K, Scattergood R O, et al. The thermal stability of high-energy ball-milled nanostructured Cu[J]. Mater Des, 2013,50:22.
14Eckert J, Holzer J C, Johnson W L. Thermal stability and grain growth behavior of mechanically alloyed nanocrystalline Fe-Cu alloys[J]. J Appl Phys, 1993, 73:131.
15Mojtahedi M, Goodarzi M, Aboutalebi M R, et al. Investigation on the formation of Cu-Fe nano crystalline super-saturated solid solution developed by mechanical alloying[J]. J Alloys Compd, 2013, 550:380.
16Fang Q, Kang Z X. An investigation on morphology and structure of Cu-Cr alloy powders prepared by mechanical milling and alloying[J]. Powder Technol, 2015,270:104.
17Suryanarayana C. Mechanical alloying and milling[J]. Prog Mater Sci, 2001, 46:1.
18He Hang, Ni Hongwei, Huang Qunxin. Nano-crystalline ultrafine grain materials produced by mechanical alloying[J]. Special Steel, 2005, 26(2):32(in Chinese).
何航,倪红卫,黄群新.机械合金化制备纳米级超细晶材料[J].特殊钢,2005, 26(2):32.
19Liao X Z, Zhao Y H, Srinivasan S G, et al. Deformation twinning in nanocrystalline copper at room temperature and low strain rate[J]. Appl Phys Lett, 2004, 84(4):592.
20Yuntian T Z, Terence G L. Influence of grain size on deformation mechanisms: An extension to nanocrystalline materials[J]. Mater Sci Eng A, 2005, 409:234.
21Yamakov V, Wolf D, Philpot S R, et al. Deformation twinning in nanocrystalline Al by molecular-dynamics simulation[J]. Acta Mater, 2002, 50 (20):5005.
22Szczerba M J, Kopacz S, Szczerba M S. Experimental studies on detwinning of face-centered cubic deformation twins[J]. Acta Mater, 2016, 104:52.
23Murayama M, Howe J M, Hidaka H, et al. Atomic-level observation of disclination dipoles in mechanically milled, nanocrystalline Fe[J]. Science, 2002, 295:2433.
24Lei R S, Wang M P, Li Z, et al. Disclination dipoles observation and nanocrystallization mechanism in ball milled Cu-Nb powders[J]. Mater Lett, 2011,65:3044.
25Wang Erde, Liu Jinglei, Liu Zuyan. The research progression on the kinetics of extension solid solubility induced by mechanical alloying[J]. Powder Metall Techonol, 2002, 20(2):109(in Chinese).
王尔德,刘京雷,刘祖岩.机械合金化诱导固溶度扩展机制研究进展[J]. 粉末冶金技术,2012, 20(2):109.
26Mula S, Bahmanpour H, Mal S, et al. Thermodynamic feasibility of solid solubility extension of Nb in Cu and their thermal stability[J]. Mater Sci Eng A, 2012, 539:330.
27Lei R S, Wang M P, Li Z, et al. Structure evolution and solid solubility extension of copper-niobium powders during mechanical alloying[J]. Mater Sci Eng A, 2011, 528:4475.
28Blavette D, Cldel E, Fraczkiewez A, et al. Three-dimensional ato-mic-scale imaging of impurity segregation to line defects[J]. Science, 1999, 286:2317.
29Veltl G. Amorphization of Cu-Ta alloys by mechanical alloying[J]. Mater Sci Eng A, 1991, 134:1410.
30Estin Y, Rabkin E. Pipe diffusion along curved dislocations: An application to mechanical alloying[J]. Scripta Mater, 1998, 39(12):1731.
31Schwarz R B. Microscopic model for mechanical alloying[J]. Mater Sci Forum, 1997, 269-272(2): 665.
32Raabe D, Ohsaki S, Hono K. Mechanical alloying and amorphization in Cu-Nb-Ag in situ composite wires studied by transmission electron microscopy and atom probe tomography[J]. Acta Mater, 2009, 57:5254.
33Guo W, Jgle E A, Choi P P, et al. Shear-induced mixing governs codeformation of crystalline-amorphous nanolaminates[J]. Phys Rev Lett, 2014, 113:035501.
34Drbohlav O, Yavari A R. Mechanical alloying and thermal decomposition of ferromagnetic nanocrystalline f.c.c.-Cu₅₀Fe₅₀[J]. Acta Mater, 1995,43:1799.
35Huang J Y, Yu Y D, Wu Y K, et al. Microstructure and nanoscale composition analysis of the mechanical alloying of Fe_xCu_100-x(x=16, 60)[J]. Acta Mater, 1997, 45:113.
36Raghu T, Sundaresan R, Ramakrishnan P, et al. Synthesis of nanocrystalline copper-tungsten alloys by mechanical alloying[J]. Mater Sci Eng A, 2001, 304-306:438.
37Yavari A R, Desre P J, Benameur T. Mechanically driven alloying of immiscible elements[J]. Phys Rev Lett, 1992, 68:2235.
38Bommnr R. Powder-metallurgical preparation and properties of superconducting Nb₃Sn and V₃Ga microcomposites[J]. J Appl Phys, 1983, 54:1479.
39Botcharova E, Freudenberger J, Schultz L. Mechanical and electrical properties of mechanically alloyed nanocrystalline Cu-Nb alloys[J]. Acta Mater, 2006, 54:3333.
40Chookajorn T, Christopher A S. Nanoscale segregation behavior and high-temperature stability of nanocrystalline W-20 at.% Ti[J]. Acta Mater, 2014,73:128.
41Chookajorn T, Heather A M, Christopher A S. Design of stable nanocrystalline alloys[J]. Science, 2012,337:951.
42Muthaiah S V M, Mula S. Effect of zirconium on thermal stability of nanocrystalline aluminium alloy prepared by mechanical alloying[J]. J Alloys Compd, 2016, 688:571.
43Kapoor M, Kaub T, Darling K, et al. An atom probe study on Nb solute partitioning and nanocrystalline grain stabilization in mechanically alloyed Cu-Nb[J]. Acta Mater, 2017,126:564.
44Frolov T, Darling K A, Kecskes L J, et al. Stabilization and strengthening of nanocrystalline copper by alloying with tantalum[J]. Acta Mater, 2012,60:2158.
45Atwater M A, Roy D, Darling K A, et al. The thermal stability of nanocrystalline copper cryogenically milled with tungsten[J]. Mater Sci Eng A, 2012, 558:226.
46Zhu C J, Ma X F, Zhao W, et al. Synthesis and thermal stability of Al₇₅W₂₅alloy obtained by mechanically alloying[J]. J Alloys Compd, 2005, 393:248.