Shahryar Mooraj, Jintao Fu, Shuai Feng, Alexander K Ng, Eric B Duoss, Sarah E Baker, Cheng Zhu, Eric Detsi, Wen Chen. Additive manufacturing of multiscale NiFeMn multi-principal element alloys with tailored composition[J]. Materials Futures, 2024, 3(4): 045103. DOI: 10.1088/2752-5724/ad89e1
Citation: Shahryar Mooraj, Jintao Fu, Shuai Feng, Alexander K Ng, Eric B Duoss, Sarah E Baker, Cheng Zhu, Eric Detsi, Wen Chen. Additive manufacturing of multiscale NiFeMn multi-principal element alloys with tailored composition[J]. Materials Futures, 2024, 3(4): 045103. DOI: 10.1088/2752-5724/ad89e1

Additive manufacturing of multiscale NiFeMn multi-principal element alloys with tailored composition

  • Abstract Nanostructured multi-principal element alloys (MPEAs) have been explored as next-generation engineering materials due to unique mechanical and functional properties which have significant advantages over traditional dilute alloys. However, the practical applications of nanostructured MPEAs are still limited due to the lack of scalable processing approaches to prepare a large quantity of nanostructured MPEAs, as well as lack of an efficient pathway for high-throughput discovery of better functional nanostructured MPEAs within their vast compositional space. Here we tackle these challenges by presenting an integrated approach by combining direct-ink-writing-based additive manufacturing, solid-state sintering, and chemical dealloying to manufacture hierarchically porous MPEAs. The hierarchical structure is comprised of macro- and micro-scale pores introduced via extrusion printing and polymer decomposition during sintering, as well as nanoscale pores formed via chemical dealloying. The macro- and micro-scale pores allow efficient dealloying of a large mass of material as the diffusion length that the corroding medium must penetrate remains at the scale of the ligaments formed after sintering (∼10 μm), despite the large volume of the 3D-printed samples. In addition, this integrated approach enables versatile control of the alloy composition via precisely tuning the ratio of elemental powders in the starting ink, thus offering a pathway for high-throughput discovery of novel functional MPEAs. As a case study, multiscale macro/micro/nanoporous NiFeMn MPEAs with three different compositions were investigated as catalysts to reduce the overpotential of oxygen evolution reaction (OER), where NiFeMn-based electrocatalysts display composition-dependent performance such that the overpotential measured at a current of 0.5 A g-1 for OER increases in the order of Ni58Fe29Mn13 Ni64Fe26Mn10 < Ni76Fe18Mn6. This introduced manufacturing process offers new opportunities for scalable fabrication and rapid screening of nanostructured multi-component complex alloys.
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