4.7 Article

Fabrication of stainless-steel microfibers with amorphous-nanosized microstructure with enhanced mechanical properties

Journal

SCIENTIFIC REPORTS
Volume 12, Issue 1, Pages -

Publisher

NATURE PORTFOLIO
DOI: 10.1038/s41598-022-14475-5

Keywords

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Funding

  1. KMM-VIN
  2. European Research Council under the Advanced Grant INTELHYB -Next generation of complex metallic materials in intelligent hybrid structures [ERC-2013-ADG-340025]
  3. Austrian Science Fund (FWF) [I3937-N36]

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Metallic glasses have gained attention for their hardness and corrosion resistance. A new method has been proposed to fabricate metallic glass microfibers using commercially available alloy compositions. The microfibers show significantly increased hardness and further enhancement of strength through heat treatment.
Metallic glasses (MG) have attracted much attention due to their superior hardness and good corrosion resistance. However, designing new MG compositions is still a big challenge, and their integration into different systems is limited when they are in the shape of bulk materials. Here, we present a new method for the fabrication of MG in the form of microfibers which could greatly help them to be integrated within different systems. The newly proposed technique has the ability to form MG structure from commercially available alloy compositions thanks to its significantly improved quenching rate(similar to 10(8) K.s(-1)). In this technique, individual melt droplets are ejected on a rotating wheel forming a thin film which are ruptured upon solidification leading to the formation of MG microfibers. In this regard, we have fabricated microfibers from a commercial DIN 1.4401 stainless-steel which could form a completely amorphous structure confirmed by DSC, XRD, and HRTEM. The fabricated MG microfibers show an increased hardness for more than two-fold from 3.5 +/- 0.17 GPa for the as-received stainless-steel to 7.77 +/- 0.60 GPa for the amorphous microfibers. Subsequent heat-treatment of the microfibers resulted in a nanocrystalline structure with the presence of amorphous regions when the hardness increases even further to 13.5 +/- 2.0 GPa. We propose that confinement of both shear transformation zones and dislocations in the heat-treated MG microfibers plays a major role in enhancing strength.

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