High-Temperature Phases in the Fe–Mo–Cr–C System
Phase equilibria involving the stable high-temperature quaternary χ Fe,Cr,Mo,C phase were established in the Fe–Mo–Cr–C phase diagram. The arc-melted alloys were annealed at subsolidus temperatures for 52 h and then quenched in liquid gallium. The solidus temperature of the alloys was determined wit...
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Veröffentlicht in: | Powder metallurgy and metal ceramics 2023, Vol.61 (9-10), p.613-624 |
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Sprache: | eng |
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Zusammenfassung: | Phase equilibria involving the stable high-temperature quaternary χ
Fe,Cr,Mo,C
phase were established in the Fe–Mo–Cr–C phase diagram. The arc-melted alloys were annealed at subsolidus temperatures for 52 h and then quenched in liquid gallium. The solidus temperature of the alloys was determined with the Pirani–Alterthum method. High-temperature X-ray diffractometry was employed to monitor the sequence of changes in the alloy phase composition from room temperature to the solidus temperature. The χ + η + α,
χ
+ η, and χ + σ phase equilibria were directly observed at 973 K < T < 1373 K, 1273 K < T < 1530 K, and 1523 K < T < 1530 K, respectively, in the Fe
52.5
Mo
23.5
Cr
18.7
C
5.3
(at.%) alloy. The χ + M
23
C
6
+ α and χ + σ phase equilibria were directly observed at 973 K ≤ T < 1523 K and 1473 K < T < 1525 K in the Fe
55.5
Mo
11.8
Cr
28.2
C
4.5
(at.%) alloy. It was shown that the two-phase χ + σ equilibrium could be preceded by three-phase χ + η + σ equilibria or a single-phase χ
Fe,Cr,Mo,C
equilibrium region (for the Fe
52.5
Mo
23.5
Cr
18.7
C
5.3
alloy in the 1523 K < T < 1530 K temperature range). The quaternary χ
Fe,Cr,Mo,C
phase was found in the (51.9–64.9) Fe, (5.4–23.5) Mo, (14.5–35.4) Cr, and (1–10.7) C at.% composition ranges. Primary crystallization regions of the σ
Fe,Cr,Mo,C
and α
Fe,Cr,Mo,C
phases with solidus temperatures of approximately 1530 K (for the Fe
52.5
Mo
23.5
Cr
18.7
C
5.3
alloy) and 1525 K (for the Fe
55.5
Mo
11.8
Cr
28.2
C
4.5
alloy) were revealed. The linear thermal expansion coefficients for the χ
Fe,Cr,Mo,C
, η
Fe,Cr,Mo,C
, and α
Fe,Cr,Mo,C
phases of different composition observed for different temperature ranges were determined. |
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ISSN: | 1068-1302 1573-9066 |
DOI: | 10.1007/s11106-023-00350-z |