Metallic Iron or a Fe-Based Glassy Alloy to Reinforce Aluminum: Reactions at the Interface during Spark Plasma Sintering and Mechanical Properties of the Composites Full article
| Journal |
Journal of Composites Science
ISSN: 2504-477X |
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| Output data | Year: 2023, Volume: 7, Number: 7, Article number : 302, Pages count : 14 DOI: 10.3390/jcs7070302 | ||||||||||||||||
| Tags | metallic glass; reinforcement; aluminum; interface; spark plasma sintering; composite; microstructure; hardness; compressive strength | ||||||||||||||||
| Authors |
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| Affiliations |
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Funding (2)
| 1 | Министерство науки и высшего образования Российской Федерации | FWGG-2021-0013 |
| 2 | Министерство науки и высшего образования Российской Федерации | FWGG-2021-0005 |
Abstract:
The microstructural features and mechanical properties of composites formed by spark
plasma sintering (SPS) of Al + 20 vol.% Fe and Al + 20 vol.% Fe66Cr10Nb5B19 (glassy alloy) mixtures
composed of micrometer-sized particles are presented. The interaction between the mixture components was studied by differential thermal analysis and through examining the microstructure of
composites sintered at two different SPS pressures. When the pressure was increased from 40 MPa to
80 MPa, the thickness of the reaction products formed between the iron particles and aluminum increased due to a more intimate contact between the phases established at a higher pressure. When the
metallic glass was substituted for iron, the pressure increase had an opposite effect. It was concluded
that local overheating at the interface in the case of Al + 20 vol.% Fe66Cr10Nb5B19 composites governed the formation of the product layers at 40 MPa. The influence of the nature of reinforcement on
the mechanical properties of the composites was analyzed, for which sintered materials with similar
microstructural features were compared. In composites without the reaction products and composites
with thin layers of the products, the hardness increased by 13–38% relative to the unreinforced
sintered aluminum, the glassy alloy and iron inclusions producing similar outcomes. The effect of the
nature of added particles on the hardness and compressive strength of composites was seen when
the microstructure of the material was such that an efficient load transfer mechanism was operative.
This was possible upon the formation of thick layers of reaction products. Upon compression, the
strong glassy cores experienced fracture, the composite with the glassy component showing a higher
strength than the composite containing core-shell structures with metallic iron cores.
Cite:
Dudina D.V.
, Kvashnin V.I.
, Bokhonov B.B.
, Legan M.A.
, Novoselov A.N.
, Bespalko Y.N.
, Jorge Jr. A.M.
, Koga G.Y.
, Ukhina A.V.
, Shtertser A.A.
, Anisimov A.G.
, Georgarakis K.
Metallic Iron or a Fe-Based Glassy Alloy to Reinforce Aluminum: Reactions at the Interface during Spark Plasma Sintering and Mechanical Properties of the Composites
Journal of Composites Science. 2023. V.7. N7. 302 :1-14. DOI: 10.3390/jcs7070302 WOS Scopus РИНЦ OpenAlex
Metallic Iron or a Fe-Based Glassy Alloy to Reinforce Aluminum: Reactions at the Interface during Spark Plasma Sintering and Mechanical Properties of the Composites
Journal of Composites Science. 2023. V.7. N7. 302 :1-14. DOI: 10.3390/jcs7070302 WOS Scopus РИНЦ OpenAlex
Dates:
| Submitted: | Jun 10, 2023 |
| Accepted: | Jul 20, 2023 |
| Published online: | Jul 23, 2023 |
Identifiers:
| Web of science: | WOS:001036018900001 |
| Scopus: | 2-s2.0-85166437312 |
| Elibrary: | 54385029 |
| OpenAlex: | W4385201611 |