Effect of intercritical annealing on the microstructure and mechanical properties of a PH 13-8 Mo maraging steel
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In: Materials science and engineering: A, Structural materials: properties, microstructure and processing, Vol. 895.2024, No. March, 146220, 03.2024.
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TY - JOUR
T1 - Effect of intercritical annealing on the microstructure and mechanical properties of a PH 13-8 Mo maraging steel
AU - Rosenauer, Andreas
AU - Teusl, Sebastian
AU - Landefeld, Andreas
AU - Brandl, Dominik
AU - Ressel, Gerald
AU - Hönigmann, Thomas
AU - Stadler, Manfred
AU - Turk, Christoph
AU - Maawad, Emad
AU - Stockinger, Martin
AU - Schnitzer, Ronald
N1 - Publisher Copyright: © 2024 The Author(s)
PY - 2024/3
Y1 - 2024/3
N2 - One method of achieving exceptional ductility and toughness of PH 13-8 Mo maraging steels is to perform aging at high temperatures or for prolonged dwell times, which is referred to as overaging. The increase in ductility and toughness is primarily related to the formation of high amounts of reverted austenite during aging. An alternative approach to elevate the reverted austenite content is to perform intercritical annealing, i.e., annealing in the dual phase field of martensite and austenite, prior to aging. Due to partitioning of substitutional elements during intercritical annealing, the freshly formed martensite is enriched in Ni after cooling. As a result, the formation of reverted austenite is facilitated, and high phase fractions can be achieved even at moderate aging temperatures. This study aims to shed light on the full potential of implementing intercritical annealing in the heat treatment route of PH 13-8 Mo maraging steels by thoroughly investigating the effect of this heat treatment adaption on the microstructure, mechanical properties and austenite stability. Overall, it is demonstrated that the addition of intercritical annealing enables to achieve a well-balanced microstructure showing a promising combination of strength, ductility and toughness. By performing intercritical annealing for shorter dwell times, high reverted austenite contents comparable to those after overaging can be reached. Resulting from a moderate aging temperature, fine β-NiAl precipitates, which were detected by atom probe tomography, are formed within martensite, leading to considerably higher strength compared to after overaging. However, the high matrix strength restricts the mechanically induced transformation of reverted austenite to martensite, as found by in-situ high-energy X-ray diffraction tensile tests.
AB - One method of achieving exceptional ductility and toughness of PH 13-8 Mo maraging steels is to perform aging at high temperatures or for prolonged dwell times, which is referred to as overaging. The increase in ductility and toughness is primarily related to the formation of high amounts of reverted austenite during aging. An alternative approach to elevate the reverted austenite content is to perform intercritical annealing, i.e., annealing in the dual phase field of martensite and austenite, prior to aging. Due to partitioning of substitutional elements during intercritical annealing, the freshly formed martensite is enriched in Ni after cooling. As a result, the formation of reverted austenite is facilitated, and high phase fractions can be achieved even at moderate aging temperatures. This study aims to shed light on the full potential of implementing intercritical annealing in the heat treatment route of PH 13-8 Mo maraging steels by thoroughly investigating the effect of this heat treatment adaption on the microstructure, mechanical properties and austenite stability. Overall, it is demonstrated that the addition of intercritical annealing enables to achieve a well-balanced microstructure showing a promising combination of strength, ductility and toughness. By performing intercritical annealing for shorter dwell times, high reverted austenite contents comparable to those after overaging can be reached. Resulting from a moderate aging temperature, fine β-NiAl precipitates, which were detected by atom probe tomography, are formed within martensite, leading to considerably higher strength compared to after overaging. However, the high matrix strength restricts the mechanically induced transformation of reverted austenite to martensite, as found by in-situ high-energy X-ray diffraction tensile tests.
KW - Atom probe tomography
KW - Austenite stability
KW - In-situ HE-XRD tensile testing
KW - Intercritical annealing
KW - Maraging steel
KW - Ni partitioning
UR - http://www.scopus.com/inward/record.url?scp=85186597874&partnerID=8YFLogxK
U2 - 10.1016/j.msea.2024.146220
DO - 10.1016/j.msea.2024.146220
M3 - Article
VL - 895.2024
JO - Materials science and engineering: A, Structural materials: properties, microstructure and processing
JF - Materials science and engineering: A, Structural materials: properties, microstructure and processing
SN - 0921-5093
IS - March
M1 - 146220
ER -