In situ tempering of martensite during laser powder bed fusion of Fe-0.45C steel
Journal article, 2022

During laser powder bed fusion (L-PBF), materials experience cyclic re-heating as new layers are deposited, inducing an in situ tempering effect. In this study, the effect of this phenomenon on the tempering of martensite during L-PBF was examined for Fe-0.45C steel. Detailed scanning electron microscopy, transmission electron microscopy, atom probe tomography, and hardness measurements indicated that martensite was initially in a quenched-like state after layer solidification, with carbon atoms segregating to dislocations and to martensite lath boundaries. Subsequent tempering of this quenched-like martensite was the result of two in situ phenomena: (i) micro-tempering within the heat affected zone and (ii) macro-tempering due to heat conduction and subsequent heat accumulation. Hardness measurements showed that although both influenced martensite tempering, micro-tempering had the most significant effect, as it reduced martensite hardness by up to ∼380 HV. This reduction was due to the precipitation of nano-sized Fe3C carbides at the previously carbon-enriched boundaries. Lastly, the magnitude of in situ tempering was found to be related to the energy input, where increasing the volumetric energy density from 60 to 190 J/mm3 reduced martensite hardness by ∼100 HV. These findings outline the stages of martensite tempering during L-PBF and indicate that the level of tempering can be adjusted by tailoring the processing parameters.

In situ tempering

Additive Manufacturing

Carbon steel

Laser powder bed fusion

Intrinsic heat treatment

Martensite

Author

William Hearn

Chalmers, Industrial and Materials Science, Materials and manufacture

Kristina Lindgren

Chalmers, Physics, Microstructure Physics

Johan Persson

Lund University

Eduard Hryha

Chalmers, Industrial and Materials Science, Materials and manufacture

Materialia

25891529 (eISSN)

Vol. 23 101459

Subject Categories

Manufacturing, Surface and Joining Technology

Metallurgy and Metallic Materials

Areas of Advance

Materials Science

DOI

10.1016/j.mtla.2022.101459

More information

Latest update

1/3/2024 9