nach oben

Journal of Materials Science

Erschienen in:

09.03.2018 | Mechanochemical Synthesis

Phase formation under non-equilibrium processing conditions: rapid solidification processing and mechanical alloying

verfasst von: C. Suryanarayana

Erschienen in: Journal of Materials Science | Ausgabe 19/2018

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Rapid solidification processing (RSP) of metallic alloys, involving solidification of liquid metals at very high rates, results in the formation of a variety of metastable phases such as supersaturated solid solutions, crystalline intermetallic compounds, quasicrystalline phases, and metallic glasses. Additionally, significant refinement of the grain sizes and segregation patterns also occurs. Mechanical alloying (MA), another powerful non-equilibrium processing technique, utilizes repeated cold welding, fracturing, and rewelding of powder particles in a high-energy ball mill. MA also results in the formation of metastable phases and microstructural refinement similar to what happens during RSP. Consequently, comparisons are frequently made between the phases produced by RSP and MA and the general understanding is that they both result in similar metastable effects. A detailed analysis of the metastable phases produced by RSP and MA is made in the present work, and it is shown that even though the effects may appear similar, the mechanisms of formation and the composition ranges in which particular phases form are quite different. These two methods also have some unique features and produce different phases. The differences have been ascribed to the fact that RSP involves solidification from the melt while MA is a completely solid-state process that is not restricted by the phase diagram.

Vorheriger Artikel Nanoscale mechanisms for high-pressure mechanochemistry: a phase field study

Nächster Artikel The effect of ball mass on the mechanochemical transformation of a single-component organic system: anhydrous caffeine

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Suryanarayana C (ed) (1999) Non-equilibrium processing of materials. Pergamon, Oxford

Suryanarayana C (1984) Metallic glasses. Bull Mater Sci 6:579–594CrossRef

Liebermann HH (ed) (1993) Rapidly solidified alloys: processes, structures, properties, applications. Marcel Dekker, New York

Suryanarayana C, Inoue A (2018) Bulk metallic glasses, 2nd edn. CRC Press, Boca Raton

Suryanarayana C, Jones H (1988) Formation and characteristics of quasicrystalline phases: a review. Int J Rapid Solidif 3:253–293

Trebin HR (ed) (2003) Quasicrystals: structure and physical properties. Wiley-VCH, Weinheim

Suryanarayana C (1995) Nanocrystalline materials. Int Mater Rev 40:41–64CrossRef

Gleiter H (2000) Nanostructured materials: basic concepts and microstructure. Acta Mater 48:1–29CrossRef

Suryanarayana C (2005) Recent developments in nanostructured materials. Adv Eng Mater 7:983–992CrossRef

10.

Turnbull D (1981) Metastable structures in metallurgy. Metall Trans A 12:695–708CrossRef

11.

Martin G, Bellon P (1997) Driven alloys. Solid State Phys 50:189–331CrossRef

12.

Duwez P, Willens RH, Klement W Jr (1960) Continuous series of metastable solid solutions in Ag–Cu alloys. J Appl Phys 31:1136–1137CrossRef

13.

Duwez P, Willens RH, Klement W Jr (1960) Metastable electron compound in Ag–Ge alloys. J Appl Phys 31:1137CrossRef

14.

Klement W Jr, Willens RH, Duwez (1960) Non-crystalline structure in solidified gold–silicon alloys. Nature 187:869–870CrossRef

15.

Duwez P (1967) Structure and properties of alloys rapidly quenched from the liquid state. Trans ASM Q 60:607–633

16.

Suryanarayana C (1991) In: Cahn RW (ed) Processing of metals and alloys. Materials science and technology: a comprehensive treatment, vol 15. VCH, Weinheim, pp 57–110

17.

Jones H (2001) A perspective on the development of rapid solidification and nonequilibrium processing and its future. Mater Sci Eng A304(306):11–19CrossRef

18.

Nishiyama N, Takenaka K, Miura H, Saido N, Zeng YQ, Inoue A (2012) The world’s biggest glassy alloy ever made. Intermetallics 30:19–24CrossRef

19.

Suryanarayana C, Inoue A (2013) Iron-based bulk metallic glasses. Int Mater Rev 58:131–166CrossRef

20.

Suryanarayana C (2002) Rapid solidification processing. In: Buschow KHJ, Cahn RW, Flemings MC, Kramer EJ, Mahajan S (eds) Encyclopedia of materials: science and technology—updates. Pergamon Press, Oxford, pp 1–10

21.

Benjamin JS (1990) Mechanical alloying: a perspective. Metal Powder Rep 45:122–127CrossRef

22.

Suryanarayana C, Klassen T, Ivanov E (2011) Synthesis of nanocomposites and amorphous alloys by mechanical alloying. J Mater Sci 46:6301–6315. https://doi.org/10.1007/s10853-011-5287-0 CrossRef

23.

Suryanarayana C (2001) Mechanical alloying and milling. Prog Mater Sci 46:1–184CrossRef

24.

Suryanarayana C (2004) Mechanical alloying and milling. Marcel Dekker, New YorkCrossRef

25.

Takacs L (2002) Self-sustaining reactions induced by ball milling. Prog Mater Sci 47:355–414CrossRef

26.

Suryanarayana C, Al-Aqeeli N (2013) Mechanically alloyed nanocomposites. Prog Mater Sci 58:383–502CrossRef

27.

Anantharaman TR, Suryanarayana C (1971) A decade of quenching from the melt. J Mater Sci 6:1111–1135. https://doi.org/10.1007/BF00980610 CrossRef

28.

Jones H (1982) Rapid solidification of metals and alloys. The Institution of Metallurgists, London

29.

Uenishi K, Kobayashi KF, Ishihara KN, Shingu PH (1991) Formation of supersaturated solid solution in the Ag–Cu system by mechanical alloying. Mater Sci Eng A134:1342–1345CrossRef

30.

Linde RK (1966) Lattice parameters of metastable silver–copper alloys. J Appl Phys 37:934CrossRef

31.

Suryanarayana C, Froes FH (1990) Nanocrystalline titanium–magnesium alloys through mechanical alloying. J Mater Res 5:1880–1886CrossRef

32.

Suryanarayana C, Liu JL (2012) Processing and characterization of mechanically alloyed immiscible metals. Int J Mater Res 103:1125–1129CrossRef

33.

Pochet P, Tominez E, Chaffron L, Martin G (1995) Order-disorder transformation in Fe–Al under ball milling. Phys Rev B 52:4006–4016CrossRef

34.

Darken LS, Gurry RW (1954) Physical chemistry of metals. McGraw-Hill, New York

35.

Froes FH, Suryanarayana C, Russell K, Li C-G (1995) Synthesis of intermetallics by mechanical alloying. Mater Sci Eng A192(193):612–623

36.

Al-Joubori A, Suryanarayana C (2015) Synthesis of metastable NiGe₂ by mechanical alloying. Mater Des 87:520–526CrossRef

37.

Singh D, Suryanarayana C, Mertus L, Chen R-H (2003) Extended homogeneity range of intermetallic phases in mechanically alloyed Mg–Al alloys. Intermetallics 11:373–376CrossRef

38.

Al-Joubori A, Suryanarayana C (2016) Synthesis of stable and metastable phases in the Ni–Si system by mechanical alloying. Powder Technol 302:8–14CrossRef

39.

Suryanarayana C, Al-Joubori A (2018) Effect of initial composition on phase selection in Ni–Si powder blends processed by mechanical alloying. Mater Manufactur Proc 33:840–848CrossRef

40.

Datta MK, Pabi SK, Murty BS (2000) Phase fields of nickel silicides obtained by mechanical alloying in the nanocrystalline state. J Appl Phys 87:8393–8400CrossRef

41.

Zhou AJ, Zhao XB, Zhu TJ, Dasgupta T, Stiewe C, Hassdorf R, Mueller E (2010) Mechanochemical decomposition of higher manganese silicides in the ball milling process. Intermetallics 18:2051–2056CrossRef

42.

Suryanarayana C (1995) Does a disordered γ-TiAl phase exist in mechanically alloyed Ti–Al powders? Intermetallics 3:153–160CrossRef

43.

Sato K, Ishizaki K, Chen GH, Frefer A, Suryanarayana C, Froes FH (1993) Fine structure analysis of mechanically alloyed titanium aluminides. In: Moore JJ, Lavernia EJ, Froes FH (eds) Proceedings of the international conference on advanced synthesis of engineered structural materials, August 31–September 2, 1992. ASM International, Materials Park, pp 221–225

44.

Seelam UMR, Barkhordarian G, Suryanarayana C (2009) Is there a hexagonal close-packed (hcp) → face-centered cubic (fcc) allotropic transformation in mechanically milled Group IVB elements? J Mater Res 24:3454–3461CrossRef

45.

Patil U, Hong SJ, Suryanarayana C (2005) An unusual phase transformation during mechanical alloying of an Fe-based bulk metallic glass composition. J Alloy Compd 389:121–126CrossRef

46.

Sharma S, Suryanarayana C (2007) Mechanical crystallization of Fe-based amorphous alloys. J Appl Phys 102:083544-1–083544-7

47.

Sharma S, Suryanarayana C (2008) Effect of carbon addition on the glass-forming ability of mechanically alloyed Fe-based alloys. J Appl Phys 103:013504-1–013504-5

48.

Suryanarayana C, Wang WK, Iwasaki H, Masumoto T (1980) High pressure synthesis of A15 Nb₃Si phase from amorphous titanium-silicon alloys. Solid State Commun 34:861–863CrossRef

49.

Trudeau ML, Schulz R, Dussault D, Van Neste A (1990) Structural changes during high-energy ball milling of iron-based amorphous alloys: is high-energy ball milling equivalent to a thermal process? Phys Rev Lett 64:99–102CrossRef

50.

Guo FQ, Lu K (1997) Ball-milling-induced crystallization and ball-milling effect on thermal crystallization kinetics in an amorphous FeMoSiB alloy. Metall Mater Trans A28:1123–1131CrossRef

51.

Yermakov AE, Yurchikov EE, Barinov VA (1981) The magnetic properties of amorphous Y–Co alloy powders obtained by mechanical comminution. Phys Met Metallogr 52(6):50–58

52.

Yermakov AE, Barinov VA, Yurchikov EE (1982) The change in the magnetic properties of Gd–Co alloy powders during their amorphization by comminution. Phys Met Metallogr 54(5):90–96

53.

Massalski TB, Okamoto H, Subramanian PR, Kacprzak L (eds) (1990) Binary alloy phase diagrams, 2nd edn. ASM International, Materials Park

54.

Omuro K, Miura H (1995) Amorphization of mechanically alloyed Fe–C and Fe–N materials with additive elements and their concentration dependence. Mater Sci Forum 179–181:273–280CrossRef

55.

Ruhl RC, Giessen BC, Cohen M, Grant NJ (1967) New microcrystalline phases in the Nb–Ni and Ta–Ni systems. Acta Metall 15:1693–1702CrossRef

56.

Petzoldt F (1988) Synthesis and process characterization of mechanically alloyed amorphous Ni–Nb powders. J Less Common Metals 140:85–92CrossRef

57.

Giessen BC, Madhava M, Polk DE, Vander Sande J (1976) Refractory amorphous inter-transition metal alloys. Mater Sci Eng 23:145–150CrossRef

58.

Rohr L, Reimann P, Richmond T, Güntherodt HJ (1991) Refractory metallic glasses. Mater Sci Eng A133:715–717CrossRef

59.

Lee PY, Chen TR (1994) Formation of amorphous Ni–Ta alloy powders by mechanical alloying. J Mater Sci Lett 13:888–890CrossRef

60.

Lee PY, Yang JL, Lin HM (1998) Amorphization behavior in mechanically alloyed Ni–Ta powders. J Mater Sci 33:235–239. https://doi.org/10.1023/A:1004334805505 CrossRef

61.

Sakata M, Cowlam N, Davies HA (1982) In: Masumoto T, Suzuki K (eds) Proceedings of the international conference on rapidly quenched metals IV (RQ4). Japan Inst Metals, Sendai, pp 327–330

62.

Rabinkin A, Liebermann H, Pounds S, Taylor T, Reidinger F, Lui SC (1991) Amorphous TiZr; base Metglas brazing filler metals. Scripta Metall Mater 25:399–404CrossRef

63.

Murty BS, Ranganathan S, Mohan Rao M (1992) Solid state amorphization in binary Ti–Ni, Ti–Cu and ternary Ti–Ni–Cu system by mechanical alloying. Mater Sci Eng A149:231–240CrossRef

64.

Krauss W, Politis C, Weimar P (1988) Preparation and compaction of mechanically alloyed amorphous materials. Metal Powder Rep 43:231–238

65.

Buschow KHJ (1984) Stability and electrical transport properties of amorphous Ti_1−xNi_x alloys. J Phys F Metal Phys 13:563–571CrossRef

66.

Altounian Z, Shank RJ, Strom-Olsen JO (1985) Crystallization characteristics of Co–Zr metallic glasses from Co₅₂Zr₄₈ to Co₂₀Zr₈₀. J Appl Phys 58:1192–1195CrossRef

67.

Eckert J, Schultz L, Urban K (1988) Glass-forming ranges in transition metal-Zr alloys prepared by mechanical alloying. J Less Common Metals 145:283–291CrossRef

68.

Altounian Z, Volkert CA, Strom-Olsen JO (1985) Crystallization characteristics of Fe–Zr metallic glasses from Fe₄₃Zr₅₇ to Fe₂₀Zr₈₀. J Appl Phys 57:1777–1782CrossRef

69.

Altounian Z, Guo-hua T, Strom-Olsen JO (1983) Crystallization characteristics of Ni–Zr metallic glasses from Ni₂₀Zr₈₀ to Ni₇₀Zr₃₀. J Appl Phys 54:3111–3116CrossRef

70.

Eckert J, Schultz L, Hellstern E, Urban K (1988) Glass-forming range in mechanically alloyed Ni–Zr and the influence of the milling intensity. J Appl Phys 64:3224–3228CrossRef

71.

Turnbull D (1969) Under what conditions can a glass be formed? Contemp Phys 10:473–488CrossRef

72.

Inoue A (2000) Stabilization of metallic supercooled liquid and bulk amorphous alloys. Acta Mater 48:279–306CrossRef

73.

Bazlov AI, Tsarkov AA, Ketov SV, Suryanarayana C, Louzguine-Luzgin DV (2018) Effect of multiple alloying elements on the glass-forming ability, thermal stability, and crystallization behavior of Zr-based alloys. Metall Mater Trans A49:644–651CrossRef

74.

Suryanarayana C, Seki I, Inoue A (2009) A critical analysis of the glass-forming ability of alloys. J Non Cryst Solids 355:355–360CrossRef

75.

Sharma S, Vaidyanathan R, Suryanarayana C (2007) Criterion for predicting the glass-forming ability of alloys. Appl Phys Lett 90:111915CrossRef

Titel: Phase formation under non-equilibrium processing conditions: rapid solidification processing and mechanical alloying
verfasst von: C. Suryanarayana
Publikationsdatum: 09.03.2018
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 19/2018
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-018-2197-4

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 19/2018

The preparation of porous carbon spheres with hierarchical pore structure and the application for high-performance supercapacitors

Nanoscale mechanisms for high-pressure mechanochemistry: a phase field study

F anion dynamics in cation-mixed nanocrystalline LaF3: SrF2

Chemical state of chlorine in perovskite solar cell and its effect on the photovoltaic performance

Kinetics of mechanical activation of Al/CuO thermite

The influence of mechanical activation on the nanostructure of zeolite

Premium Partner

Marktübersichten