Effect of Hot Deformation on Microstructure, Hardness and Precipitation Kinetics in a C350 Maraging Steel Modified by Titanium Addition

Abstract: Maraging steels are alloys with a good balance between strength and fracture toughness. These properties are obtained by quenching and aging treatments, where the precipitation of intermetallic compounds is promoted in a martensitic matrix. In this context, this paper aims to evaluate the effect of hot deformation on microstructure, kinetics and formation of reverted austenite in a C350 maraging steel modified by titanium addition, in order to improve the mechanical properties without addition of alloying elem… Show more

“…These precipitates are metastable, coherent/semi-coherent with the matrix [21] and form in the first few minutes of aging at temperatures above 723 K [16,40,54]. The same diffraction pattern is observed in the work of Freitas [44], who also studied a high Ti content maraging C300 steel. However, due to aging at 823 K, the presence of Ni 3 (Ti, Mo) observed was smaller and overlapped by reverse austenite peaks.…”

“…However, as the tendency of precipitation kinetics is to reduce with a reduction in supersaturation and nucleation site, the increase in Ni 3 (Ti, Mo) volumetric fraction was less significant between 10 and 50 h than 0 and 10 h. Increasing aging time also generates austenite in the HF condition, only. That was also verified by Guiza [7] and Freitas [44], which showed that hot forging accelerates the austenite formation.…”

“…As the increase in the aging temperature leads to an increase in the formation of stable precipitates and reversed austenite, a reduction in the fraction of metastable precipitates and an acceleration in their dissolution, at temperatures higher than 823 K it is difficult to distinguish metastable precipitates in X-ray diffraction. In addition to phase formation, the X-ray diffraction also enables to verify the influence of deformation on crystallite size, microstrain and lattice parameter [44].…”

Structural Study of Undeformed and Deformed Maraging C300 Steels Using X-ray Diffraction Measurements

“…These precipitates are metastable, coherent/semi-coherent with the matrix [21] and form in the first few minutes of aging at temperatures above 723 K [16,40,54]. The same diffraction pattern is observed in the work of Freitas [44], who also studied a high Ti content maraging C300 steel. However, due to aging at 823 K, the presence of Ni 3 (Ti, Mo) observed was smaller and overlapped by reverse austenite peaks.…”

“…However, as the tendency of precipitation kinetics is to reduce with a reduction in supersaturation and nucleation site, the increase in Ni 3 (Ti, Mo) volumetric fraction was less significant between 10 and 50 h than 0 and 10 h. Increasing aging time also generates austenite in the HF condition, only. That was also verified by Guiza [7] and Freitas [44], which showed that hot forging accelerates the austenite formation.…”

“…As the increase in the aging temperature leads to an increase in the formation of stable precipitates and reversed austenite, a reduction in the fraction of metastable precipitates and an acceleration in their dissolution, at temperatures higher than 823 K it is difficult to distinguish metastable precipitates in X-ray diffraction. In addition to phase formation, the X-ray diffraction also enables to verify the influence of deformation on crystallite size, microstrain and lattice parameter [44].…”

Structural Study of Undeformed and Deformed Maraging C300 Steels Using X-ray Diffraction Measurements

The role of titanium on the microstructure and mechanical properties of additively manufactured C300 maraging steels

Analysis of dynamic recrystallization through austenite grain reconstruction of additively manufactured martensitic M789 steel