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Journal of Materials Science

Erschienen in:

24.10.2016 | Original Paper

Experimental investigation of phase equilibria in the Ti–Al–Mo ternary system

verfasst von: X. M. Huang, L. L. Zhu, G. M. Cai, H. S. Liu, Z. P. Jin

Erschienen in: Journal of Materials Science | Ausgabe 4/2017

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Abstract

Phase equilibria in Ti–Al–Mo ternary system are of fundamental importance to better acquire the phase-forming regulation of TiAl-based alloys. In this paper, phase relations in this system have been investigated with Ti–TiAl–Mo diffusion triples combined with key equilibrated alloys. Five isothermal sections of the Ti–Al–Mo ternary system at 1473, 1373, 1273, 1173, and 1073 K were experimentally determined by means of electron probe microanalysis, scanning electron microscope, and X-ray diffraction. The TiAl and TiAl₃ phases show wide ternary composition ranges, while the solubility of Mo in the Ti₃Al and αTi phases is relatively limited. The solubility of Al in the β(Ti, Mo) phase decreases from 49.0 at.% at 1473 K to 39.9 at.% at 1073 K while that of Ti in the AlMo₃ phase decreases from 25.4 at.% at 1473 K to 20.8 at.% at 1073 K. Moreover, the ternary compound σ forms at a temperature between 1423 and 1373 K through a peritectoid reaction β(Ti, Mo) + AlMo₃ → σ. A peri-eutectoid invariant reaction β(Ti, Mo) + AlMo₃ → σ + TiAl₃ at 1373–1273 K was further deduced and the existence of another invariant reaction β(Ti, Mo) + TiAl₃ → σ + TiAl at a temperature between 1273 and 1173 K was also confirmed. The established phase equilibria of the Ti–Al–Mo ternary system may provide essential data required for the construction of reliable thermodynamic assessment of the Ti–Al–Mo system.

Vorheriger Artikel Preparation of hybrids derived from zinc phosphate glasses and benzimidazole for anhydrous proton conduction applications

Nächster Artikel Fabrication and photoluminescence of Eu-doped KNN-based transparent ceramics

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Leyens C, Peters M (2003) Titanium and titanium alloys. Wiley, WeinheimCrossRef

Froes F, Suryanarayana C, Eliezer D (1992) Synthesis, properties and applications of titanium aluminides. J Mater Sci 27:5113–5140. doi:10.1007/BF00553381 CrossRef

Clemens H, Mayer S (2013) Design processing, microstructure, properties, and applications of advanced intermetallic TiAl alloys. Adv Eng Mater 15:191–215CrossRef

Yamaguchi M, Inui H, Ito K (2000) High-temperature structural intermetallics. Acta Mater 48:307–322CrossRef

Clemens H, Wallgram W, Kremmer S, Guther V, Otto A, Bartels A (2008) Design of novel β-solidifying TiAl alloys with adjustable β/B2-phase fraction and excellent hot-workability. Adv Eng Mater 10:707–713CrossRef

Kainuma R, Fujita Y, Mitsui H, Ohnuma I, Ishida K (2000) Phase equilibria among α (hcp), β (bcc) and γ (L1₀) phases in Ti–Al base ternary alloys. Intermetallics 8:855–867CrossRef

Chen G, Peng Y, Zheng G, Qi Z, Wang M, Yu H, Dong C, Liu CT (2016) Polysynthetic twinned TiAl single crystals for high-temperature applications. Nat Mater 15:876–881CrossRef

Li YG, Loretto MH (1994) Microstructure and fracture behaviour of Ti–44Al–xM derivatives. Acta Metall Mater 42:2913–2919CrossRef

Das S, Mishurda JC, Allen WP, Perepezko JH, Chumbley LS (1993) Development of (γ + β) lamellar microstructure in a Ti₄₅Al₅₀Mo₅ alloy. Scr Metall Mater 28:489–494CrossRef

10.

Lee HN, Johnson DR, Inui H, Oh MH, Wee DM, Yamaguchi M (2000) Microstructural control through seeding and directional solidification of TiAl alloys containing Mo and C. Acta Mater 48:3221–3233CrossRef

11.

Witusiewicz VT, Bondar AA, Hecht U, Rex S, Velikanova TY (2008) The Al–B–Nb–Ti system: III. Thermodynamic re-evaluation of the constituent binary system Al–Ti. J Alloys Compd 465:64–77CrossRef

12.

Schuster JC, Palm M (2006) Reassessment of the binary aluminum–titanium phase diagram. J Phase Equilib 27:255–277CrossRef

13.

Chung HJ, Shim JH, Lee DN (1999) Thermodynamic evaluation and calculation of phase equilibria of the Ti–Mo–C–N quaternary system. J Alloys Compd 282:142–148CrossRef

14.

Shim JH, Oh CS, Lee DN (1996) A thermodynamic evaluation of the Ti–Mo–C system. Metall Mater Trans B 27B:955–966CrossRef

15.

Cupid DM, Fabrichnaya O, Ebrahimi F, Seifert HJ (2010) Thermodynamic assessment of the Al–Mo system and of the Ti–Al–Mo System from 0 to 20 at.% Ti. Intermetallics 18:1185–1196CrossRef

16.

Du ZM, Guo CP, Li CR, Zhang WJ (2009) Thermodynamic description of the Al–Mo and Al–Fe–Mo systems. J Phase Equilib 30:487–501CrossRef

17.

Eumann M, Sauthoff G, Palm M (2006) Re-evaluation of phase equilibria in the Al–Mo system. Int J Mater Res 97:1502–1511CrossRef

18.

Jin ZP (1981) A study of the range of stability of phase in some ternary systems. Scand J Metall 10:279–287

19.

Zhao JC (2001) A combinatorial approach for structural materials. Adv Eng Mater 3:143–147CrossRef

20.

Zhao JC, Jackson MR, Peluso LA, Brewer LN (2002) A diffusion multiple approach for the accelerated design of structural materials. MRS Bull 27:324–329CrossRef

21.

Zhao JC (2004) Reliability of the diffusion-multiple approach for phase diagram mapping. J Mater Sci 39:3913–3925. doi:10.1023/B:JMSC.0000031472.25241.c5 CrossRef

22.

Van Loo FJJ (1990) Multiphase diffusion in binary and ternary solid-state systems. Prog Solid State Chem 20:47–99CrossRef

23.

Banerjee D, Krishnan RV, Vasu KI (1980) A reconsideration of phase relations in the Ti–Al–Mo and Ti–Al systems. Metall Trans A 11A:1095–1105CrossRef

24.

Chen Z, Jones IP, Small CJ (1997) Structure of the alloy Ti–50Al–15Mo between 800 and 1400 °C. Acta Mater 45:3801–3815CrossRef

25.

Kimura M, Hashimoto K, Morikawa H (1992) Study on phase stability in Ti–Al–X systems at high temperatures. Mater Sci Eng 152:54–59CrossRef

26.

Morris MA, Li YG, Leboeuf M (1994) Variation of the phase distribution in a Ti–44Al–2Mo alloy by annealing: influence on its strength and ductility. Scr Metall Mater 31:449–454CrossRef

27.

Kimura M, Hashimoto K (1999) High-temperature phase equilibria in Ti–Al–Mo system. J Phase Equilib 20:224–230CrossRef

28.

Ge DM, Pylaeva E (1966) Investigation of the phase equilibrium of the Ti–Al–Mo system in the titanium-rich alloy field. Titan Alloys 10:11–18

29.

Eremenko VN, Tretyachenko LA, Sukhaya SA, Petukh VM (1990) Investigation of the structure of alloys of the Ti–Mo–Al system. Akad Nauk Ukr 83–135

30.

Rashkova B, Hahn KS, Brabetz M, Zhang Z, Schoberl T, Clemens H, Mayer S (2015) Microstructural evolution and grain refinement in an intermetallic titanium aluminide alloy with a high molybdenum content. Int J Mater Res 106:725–731CrossRef

31.

Zangvil A, Osamura K, Murakami Y (1975) Determination of phase equilibrium in the Ti-rich Ti–Mo–Al ternary system using the X-ray microanalyser. Metal Sci 9:27–31CrossRef

32.

Böhm H, Löhberg K (1958) A superstructure CsCl type phase in the titanium–molybdenum–aluminium system. Z Metallkd 49:173–178

33.

Hansen RT, Raman A (1970) Alloy chemistry of σ(βU)-phases. III. σ phases with non-transition elements. Z Metallkd 61:115–120

34.

Hamajima T, Luetjering G, Weissmann S (1972) Microstructure and phase relations for Ti–Mo–Al alloys. Metall Trans A 3:2805–2810CrossRef

35.

Nino R, Fujinaka J, Shimamura H, Miura S, Mohri T (2003) Phase equilibria and microstructure evolution of Al–Mo–Ti ternary alloys. Intermetallics 11:611–623CrossRef

36.

Tretyachenko L (2005) Aluminum-Molybdenum-Titanium. In: Martienssen W (ed) Landolt-Boernstein New Series IV, vol (11). Plenum Press, New York, pp 287–316

37.

Singh AK, Banerjee D (1997) Transformations in α₂ + γ titanium aluminide alloys containing molybdenum: Part II. Heat treatment. Metall Mater Trans A 28:1745–1753CrossRef

38.

Raghavan V (2005) Al–Mo–Ti (aluminum–molybdenum–titanium). J Phase Equilib 26:357–359CrossRef

39.

Raghavan V (2011) Al–Mo–Ti (aluminum–molybdenum–titanium). J Phase Equilib 32:61–63CrossRef

40.

Schmoelzer T, Mayer S, Sailer C, Haupt F, Guther V, Staron P, Liss KD, Clemens H (2011) In situ diffraction experiments for the investigation of phase fractions and ordering temperatures in Ti–44at%Al–(3–7)at%Mo alloys. Adv Eng Mater 13:306–311CrossRef

41.

Kenel C, Leinenbach C (2016) Influence of Nb and Mo on microstructure formation of rapidly solidified ternary Ti–Al–(Nb, Mo) alloys. Intermetallics 69:82–89CrossRef

42.

Zhu J, Zhang C, Cao WS, Chen SL, Zhang F, Park JS, Yi SH (2015) Molar volume modeling of Ti–Al–Nb and Ti–Al–Mo ternary systems. JOM 67:1881–1885CrossRef

Titel: Experimental investigation of phase equilibria in the Ti–Al–Mo ternary system
verfasst von: X. M. Huang
L. L. Zhu
G. M. Cai
H. S. Liu
Z. P. Jin
Publikationsdatum: 24.10.2016
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 4/2017
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-016-0520-5

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