Segregation engineering of grain boundaries of a metastable Fe-Mn-Co-Cr-Si high entropy alloy with laser-powder bed fusion additive manufacturing

Saket Thapliyal, Priyanshi Agrawal, Priyanka Agrawal, Saurabh S. Nene, Rajiv S. Mishra, Brandon A. McWilliams, Kyu C. Cho

Research output: Contribution to journalArticlepeer-review

93 Scopus citations

Abstract

Laser-powder bed fusion (L-PBF) additive manufacturing offers unprecedented microstructural fine-tuning capabilities. Naturally, benefitting from such capability requires alloys that are amenable to microstructural heterogeneity and hierarchy (MHH) and that exhibit a low hot-cracking susceptibility (HCS). However, columnar growth, which is characterized by capillary effects and poor strain accommodation capabilities, is prevalent in L-PBF and increases the HCS of the processed alloys. Further, while solute segregation is prominent in cellular and dendritic growth modes during L-PBF, the effects of solute segregation on the alloy HCS and L-PBF processing window remain widely unexplored. Here, we demonstrate that solute segregation affects columnar growth, grain coalescence behavior during solidification, MHH and mechanical properties of a metastable Fe40Mn20Co20Cr15Si5 (at.%) high entropy alloy (CS-HEA) doped with 0.5 wt.% B4C (termed CS-BC). A theoretical framework is proposed, which reveals that a boundary-strengthening segregant may reduce the alloy HCS during L-PBF. In as-built CS-BC, boron, a boundary strengthener, segregated to the solidification cell boundaries, whereas carbon remained in the solid solution. The as-built CS-BC exhibited suppressed columnar growth, more random texture, smaller cell size and higher strength as compared to the as-built CS-HEA. Further, a wide crack-free L-PBF processing window of CS-BC allowed fine-tuning of its MHH and thus the mechanical properties. Upon annealing, as carbon-containing precipitates formed, CS-BC exhibited a metastable microstructure and transformation induced plasticity effect, which led to high synergistic strength-ductility. These findings will foster design of alloys that facilitate application-specific manufacture with L-PBF and thus, an extended outreach of L-PBF for structural applications.

Original languageEnglish
Article number117271
JournalActa Materialia
Volume219
DOIs
StatePublished - Oct 15 2021
Externally publishedYes

Funding

The study was performed under the cooperative agreement between University of North Texas and CCDC Army Research Laboratory (W911NF1920011). The authors thank Center for Agile and Adaptive Additive Manufacturing, Materials Research Facility (MRF) and Advanced Materials and Manufacturing Processes Institute (AMMPI) at University of North Texas for access to additive manufacturing equipment, electron microscopy and X-ray microscopy facilities, respectively.

Keywords

  • Alloy design, High entropy alloys, Transformation induced plasticity (TRIP)
  • Grain boundary segregation, Additive manufacturing, Solidification

Fingerprint

Dive into the research topics of 'Segregation engineering of grain boundaries of a metastable Fe-Mn-Co-Cr-Si high entropy alloy with laser-powder bed fusion additive manufacturing'. Together they form a unique fingerprint.

Cite this