Atom-Probe Tomographic Investigation of Austenite Stability and Carbide Precipitation in a TRIP-Assisted 10 Wt Pct Ni Steel and Its Weld Heat-Affected Zones

Newly developed low-carbon 10 wt pct Ni-Mo-Cr-V martensitic steels rely on the Ni-enriched, thermally stable austenite [formed via multistep intercritical Quench-Lamellarization-Tempering ( QLT )-treatment] for their superior mechanical properties, specifically ballistic resistance. Critical to the...

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Published in:Metallurgical and materials transactions. A, Physical metallurgy and materials science Physical metallurgy and materials science, 2018-04, Vol.49 (4), p.1031-1043
Main Authors: Jain, Divya, Seidman, David N., Barrick, Erin J., DuPont, John N.
Format: Article
Language:English
Subjects:
Austenite
Carbides
Characterization and Evaluation of Materials
Chemical precipitation
Chemistry and Materials Science
Chromium
Heat affected zone
Heat treating
Manganese
Martensite
Martensitic stainless steels
Martensitic transformations
Materials Science
Mathematical analysis
Mechanical properties
Metallic Materials
Metallurgy
Microhardness
Microstructure
Molybdenum
Nanotechnology
Nickel
Precipitates
Structural Materials
Surfaces and Interfaces
Thermal resistance
Thermal stability
Thin Films
TRIP steels
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Summary:Newly developed low-carbon 10 wt pct Ni-Mo-Cr-V martensitic steels rely on the Ni-enriched, thermally stable austenite [formed via multistep intercritical Quench-Lamellarization-Tempering ( QLT )-treatment] for their superior mechanical properties, specifically ballistic resistance. Critical to the thermal stability of austenite is its composition, which can be severely affected in the weld heat-affected zones (HAZs) and thus needs investigations. This article represents the first study of the nanoscale redistributions of C, Ni, and Mn in single-pass HAZ microstructures of QLT -treated 10 wt pct Ni steels. Local compositions of Ni-rich regions (representative of austenite compositions) in the HAZs are determined using site-specific 3-D atom-probe tomography (APT). Martensite-start temperatures are then calculated for these compositions, employing the Ghosh-Olson thermodynamic and kinetics approach. These calculations predict that austenite (present at high temperatures) in the HAZs is susceptible to a martensitic transformation upon cooling to room temperature, unlike the austenite in the QLT -treated base-metal. While C in the QLT -treated base-metal is consumed primarily in MC and M 2 C-type carbide precipitates (M is Mo, Cr, V), its higher concentration in the Ni-rich regions in the HAZs indicates the dissolution of carbide precipitates, particularly M 2 C carbide precipitates. The role of M 2 C carbide precipitates and austenite stability is discussed in relation to the increase in microhardness values observed in the HAZs, relative to the QLT -treated base-metal. Insights gained from this research on austenite stability and carbide precipitation in the single-pass HAZ microstructures will assist in designing multiple weld cycles for these novel 10 wt pct Ni steels.
ISSN:1073-5623
1543-1940
DOI:10.1007/s11661-018-4470-1