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Enhanced mechanical properties and microstructural stability of ultrafine-grained biodegradable Zn-Li-Mn-Mg-Cu alloys produced by rapid solifictaion and high-pressure torsion

Enhanced mechanical properties and microstructural stability of ultrafine-grained biodegradable Zn-Li-Mn-Mg-Cu alloys produced by rapid solifictaion and high-pressure torsion
Enhanced mechanical properties and microstructural stability of ultrafine-grained biodegradable Zn-Li-Mn-Mg-Cu alloys produced by rapid solifictaion and high-pressure torsion
Zinc alloys have emerged as promising candidates for biodegradable materials due to their remarkable biocompatibility and favorable mechanical characteristics. The incorporation of alloying elements plays an essential role in advancing the tensile strength of Zn alloys. Nevertheless, achieving uniform dispersion of these elements poses challenges due to chemical segregation during solidification. In this study, rapid solidification followed by high-pressure torsion was successfully employed to fabricate Zn-Li-Mn-Mg-Cu alloys characterized by ultrafine-grained microstructures with evenly distributed nanometric intermetallic phases. A comprehensive examination, including phase composition, microstructural evolution, tensile properties and deformation mechanisms, was conducted. The impact of varying annealing temperatures on microstructural stability was systematically examined. The combined implementation of rapid solidification and high-pressure torsion yielded alloys with an average grain size below 360 nm, thereby demonstrating exceptional mechanical properties including yield stress (YS), ultimate tensile strength (UTS), and elongation to failure (Ef) equal to at least 325±6 MPa, 350±8 MPa and 40±11 %, respectively. Heat treatment notably augmented the mechanical properties, resulting in a YS = 440±11 MPa and UTS = 491±6 MPa, while preserving plasticity (Ef = 23±4 %) in the Zn-0.33Li-0.27Mn-0.14Mg-0.1Cu alloy. Nanoindentation strain rate jump tests identified thermally activated mechanisms and grain boundary sliding as dominant deformation mechanisms.
deformation mechanisms, high-pressure torsion, mechanical properties, rapid solidification, zinc alloys
0025-5416
Bednarczyka, Wiktor
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Watroba, Maria
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Cieślak, Grzegorz
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Ciemiorek, Marta
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Hamulka, Kamila
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Schreiner, Claudia
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Figi, Renato
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Marciszko-Wiąckowskad, Marianna
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Cios, Grzegorz
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Schwiedrzik, Jakob
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Michler, Johann
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Gao, Nong
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Lewandowska, Malgorzata
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Langdon, Terence G.
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Bednarczyka, Wiktor
11880ae3-e637-4883-b395-80e642702620
Watroba, Maria
0907548f-be5b-4611-acbb-f0a8830d79b4
Cieślak, Grzegorz
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Ciemiorek, Marta
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Hamulka, Kamila
54b18866-a773-43d3-bbd7-e128859ee847
Schreiner, Claudia
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Figi, Renato
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Marciszko-Wiąckowskad, Marianna
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Cios, Grzegorz
e7e3313f-e8f5-469a-b68f-decc6b169764
Schwiedrzik, Jakob
145a8209-8c96-4628-89e8-c1f351786805
Michler, Johann
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Gao, Nong
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Lewandowska, Malgorzata
c574d02d-d34d-4164-8ed1-90c3d77584d2
Langdon, Terence G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86

Bednarczyka, Wiktor, Watroba, Maria, Cieślak, Grzegorz, Ciemiorek, Marta, Hamulka, Kamila, Schreiner, Claudia, Figi, Renato, Marciszko-Wiąckowskad, Marianna, Cios, Grzegorz, Schwiedrzik, Jakob, Michler, Johann, Gao, Nong, Lewandowska, Malgorzata and Langdon, Terence G. (2024) Enhanced mechanical properties and microstructural stability of ultrafine-grained biodegradable Zn-Li-Mn-Mg-Cu alloys produced by rapid solifictaion and high-pressure torsion. Materials Science and Engineering, 892, [146027]. (doi:10.1016/j.msea.2023.146027).

Record type: Article

Abstract

Zinc alloys have emerged as promising candidates for biodegradable materials due to their remarkable biocompatibility and favorable mechanical characteristics. The incorporation of alloying elements plays an essential role in advancing the tensile strength of Zn alloys. Nevertheless, achieving uniform dispersion of these elements poses challenges due to chemical segregation during solidification. In this study, rapid solidification followed by high-pressure torsion was successfully employed to fabricate Zn-Li-Mn-Mg-Cu alloys characterized by ultrafine-grained microstructures with evenly distributed nanometric intermetallic phases. A comprehensive examination, including phase composition, microstructural evolution, tensile properties and deformation mechanisms, was conducted. The impact of varying annealing temperatures on microstructural stability was systematically examined. The combined implementation of rapid solidification and high-pressure torsion yielded alloys with an average grain size below 360 nm, thereby demonstrating exceptional mechanical properties including yield stress (YS), ultimate tensile strength (UTS), and elongation to failure (Ef) equal to at least 325±6 MPa, 350±8 MPa and 40±11 %, respectively. Heat treatment notably augmented the mechanical properties, resulting in a YS = 440±11 MPa and UTS = 491±6 MPa, while preserving plasticity (Ef = 23±4 %) in the Zn-0.33Li-0.27Mn-0.14Mg-0.1Cu alloy. Nanoindentation strain rate jump tests identified thermally activated mechanisms and grain boundary sliding as dominant deformation mechanisms.

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Bednarczyk-Revised Manusript WB-TGL - Accepted Manuscript
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Accepted/In Press date: 18 December 2023
e-pub ahead of print date: 24 December 2023
Published date: February 2024
Keywords: deformation mechanisms, high-pressure torsion, mechanical properties, rapid solidification, zinc alloys

Identifiers

Local EPrints ID: 485930
URI: http://eprints.soton.ac.uk/id/eprint/485930
ISSN: 0025-5416
PURE UUID: 9e8d8976-7c35-43bd-ad8d-4784f2996b0d
ORCID for Nong Gao: ORCID iD orcid.org/0000-0002-7430-0319
ORCID for Terence G. Langdon: ORCID iD orcid.org/0000-0003-3541-9250

Catalogue record

Date deposited: 04 Jan 2024 04:55
Last modified: 29 Oct 2024 05:02

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Contributors

Author: Wiktor Bednarczyka
Author: Maria Watroba
Author: Grzegorz Cieślak
Author: Marta Ciemiorek
Author: Kamila Hamulka
Author: Claudia Schreiner
Author: Renato Figi
Author: Marianna Marciszko-Wiąckowskad
Author: Grzegorz Cios
Author: Jakob Schwiedrzik
Author: Johann Michler
Author: Nong Gao ORCID iD
Author: Malgorzata Lewandowska

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