Effect of Volumetric Energy Density on the Evolution of the Microstructure and the Degradation Behavior of 3D-Printed Fe-Mn-C Alloys from Water-Atomized Powders

Effect of Volumetric Energy Density on the Evolution of the Microstructure and the Degradation Behavior of 3D-Printed Fe-Mn-C Alloys from Water-Atomized Powders

Additive manufacturing of metals opens new doors for innovation in custom-based productions in a wide range of fields, including medicine, even if it introduces new challenges that need to be addressed to guarantee the properties are equal to or superior to those of conventional fabrication processe...

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Bibliographic Details
Main Authors: Quang Nguyen Cao, Abdelhakim Cherqaoui, Carlos Henrique Michelin Beraldo, Carlo Paternoster, Simon Gélinas, Carl Blais, Paolo Mengucci, Diego Mantovani
Format: Article
Language:English
Published: MDPI AG 2025-01-01
Series:Metals
Subjects:
3D printing
Fe-based alloys
porosity
degradation
biodegradable metals
Online Access:https://www.mdpi.com/2075-4701/15/2/101
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Summary:Additive manufacturing of metals opens new doors for innovation in custom-based productions in a wide range of fields, including medicine, even if it introduces new challenges that need to be addressed to guarantee the properties are equal to or superior to those of conventional fabrication processes. In this research, porous, biodegradable Fe-Mn-C alloys were fabricated using a 3D printing technique with four different printing energy densities ranging from 62.5 to 125.0 J/mm<sup>3</sup>. The effect of printing energy density on the microstructure and degradation behavior was investigated. Lower energy densities resulted in higher pore density and the presence of unmelted powder particles, while the alloy printed at 104.2 J/mm<sup>3</sup> exhibited the lowest pore density and the smallest grain size. Degradation tests revealed that the highest pore density in the sample printed at 62.5 J/mm<sup>3</sup>, and the lowest grain size in the sample printed at 104.2 J/mm<sup>3</sup> contributed to faster degradation rates. The alloy printed at the highest energy density, 125.0 J/mm<sup>3</sup>, demonstrated the largest grain size and the slowest degradation rate. Energy-dispersive spectroscopy and Fourier transform infrared spectroscopy analyses identified manganese carbonate as the primary degradation product, with calcium phosphate forming as a secondary product. These findings provide a significant understanding of the relationship between printing parameters, microstructure, and degradation behavior, which are essential for optimizing the performance of Fe-Mn-C alloys in biodegradable material applications.
ISSN:2075-4701

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