Long term hydrogen storage properties of ZK60 Mg-alloy as processed by different methods of SPD

P. Cengeri; Y. Kimoto; M. Janoska; Z. Abbasi; Y. Morisada; H. Fujii; N. Enzinger; Ch Sommitsch; G. Boczkal; G. Krexner; M. J. Zehetbauer; E. Schafler

doi:10.1007/s10853-024-09529-0

Long term hydrogen storage properties of ZK60 Mg-alloy as processed by different methods of SPD

P. Cengeri, Y. Kimoto, M. Janoska, Z. Abbasi, Y. Morisada, H. Fujii, N. Enzinger, Ch Sommitsch, G. Boczkal, G. Krexner, M. J. Zehetbauer^*, E. Schafler

^*Corresponding author for this work

Institute of Materials Science, Joining and Forming (3030)

Research output: Contribution to journal › Article › peer-review

Abstract

Hydrogen storage characteristics is studied in the Mg-alloy ZK60 after processing by different SPD (Severe Plastic Deformation) methods such as High Pressure Torsion (HPT) and Friction Stir Processing (FSP), applying various deformation extents and rates. The capacity and kinetics of hydrogen storage was investigated and analysed, up to 100 storage cycles. While the degree of SPD deformation is less important for the storage capacity, the SPD processing method itself matters, yielding about ~ 30% more capacity in FSP than in HPT. As shown by DSC and XRD analyses, it is the density of SPD-induced vacancy agglomerates which is significantly higher in FSP than in HPT (~ 10^–3 instead of ~ 10^–4) because of the enhanced dislocation slip activity. Thanks to their stabilization through Mg(Zn,Zr) precipitates, the vacancy agglomerates survive numerous cycles of hydrogen storage in spite of the high storage temperature of 350 °C, and can act as thermally stable heterogeneous nuclei for the hydrogenation. This latter mechanism was found in all SPD methods applied irrespective of the deformation extent, on the basis of Johnson–Mehl–Avrami-Kolmogorov analysis providing the Avrami exponent n = 1, already from the second up to the highest hydrogen storage cycles.

Original language	English
Pages (from-to)	5906-5922
Number of pages	17
Journal	Journal of Materials Science
Volume	59
Issue number	14
DOIs	https://doi.org/10.1007/s10853-024-09529-0
Publication status	Published - Apr 2024

ASJC Scopus subject areas

Ceramics and Composites
Materials Science (miscellaneous)
General Materials Science
Mechanics of Materials
Mechanical Engineering
Polymers and Plastics

Fields of Expertise

Advanced Materials Science

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "Long term hydrogen storage properties of ZK60 Mg-alloy as processed by different methods of SPD",

abstract = "Hydrogen storage characteristics is studied in the Mg-alloy ZK60 after processing by different SPD (Severe Plastic Deformation) methods such as High Pressure Torsion (HPT) and Friction Stir Processing (FSP), applying various deformation extents and rates. The capacity and kinetics of hydrogen storage was investigated and analysed, up to 100 storage cycles. While the degree of SPD deformation is less important for the storage capacity, the SPD processing method itself matters, yielding about ~ 30% more capacity in FSP than in HPT. As shown by DSC and XRD analyses, it is the density of SPD-induced vacancy agglomerates which is significantly higher in FSP than in HPT (~ 10–3 instead of ~ 10–4) because of the enhanced dislocation slip activity. Thanks to their stabilization through Mg(Zn,Zr) precipitates, the vacancy agglomerates survive numerous cycles of hydrogen storage in spite of the high storage temperature of 350 °C, and can act as thermally stable heterogeneous nuclei for the hydrogenation. This latter mechanism was found in all SPD methods applied irrespective of the deformation extent, on the basis of Johnson–Mehl–Avrami-Kolmogorov analysis providing the Avrami exponent n = 1, already from the second up to the highest hydrogen storage cycles.",

author = "P. Cengeri and Y. Kimoto and M. Janoska and Z. Abbasi and Y. Morisada and H. Fujii and N. Enzinger and Ch Sommitsch and G. Boczkal and G. Krexner and Zehetbauer, {M. J.} and E. Schafler",

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doi = "10.1007/s10853-024-09529-0",

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T1 - Long term hydrogen storage properties of ZK60 Mg-alloy as processed by different methods of SPD

AU - Cengeri, P.

AU - Kimoto, Y.

AU - Janoska, M.

AU - Abbasi, Z.

AU - Morisada, Y.

AU - Fujii, H.

AU - Enzinger, N.

AU - Sommitsch, Ch

AU - Boczkal, G.

AU - Krexner, G.

AU - Zehetbauer, M. J.

AU - Schafler, E.

PY - 2024/4

Y1 - 2024/4

N2 - Hydrogen storage characteristics is studied in the Mg-alloy ZK60 after processing by different SPD (Severe Plastic Deformation) methods such as High Pressure Torsion (HPT) and Friction Stir Processing (FSP), applying various deformation extents and rates. The capacity and kinetics of hydrogen storage was investigated and analysed, up to 100 storage cycles. While the degree of SPD deformation is less important for the storage capacity, the SPD processing method itself matters, yielding about ~ 30% more capacity in FSP than in HPT. As shown by DSC and XRD analyses, it is the density of SPD-induced vacancy agglomerates which is significantly higher in FSP than in HPT (~ 10–3 instead of ~ 10–4) because of the enhanced dislocation slip activity. Thanks to their stabilization through Mg(Zn,Zr) precipitates, the vacancy agglomerates survive numerous cycles of hydrogen storage in spite of the high storage temperature of 350 °C, and can act as thermally stable heterogeneous nuclei for the hydrogenation. This latter mechanism was found in all SPD methods applied irrespective of the deformation extent, on the basis of Johnson–Mehl–Avrami-Kolmogorov analysis providing the Avrami exponent n = 1, already from the second up to the highest hydrogen storage cycles.

AB - Hydrogen storage characteristics is studied in the Mg-alloy ZK60 after processing by different SPD (Severe Plastic Deformation) methods such as High Pressure Torsion (HPT) and Friction Stir Processing (FSP), applying various deformation extents and rates. The capacity and kinetics of hydrogen storage was investigated and analysed, up to 100 storage cycles. While the degree of SPD deformation is less important for the storage capacity, the SPD processing method itself matters, yielding about ~ 30% more capacity in FSP than in HPT. As shown by DSC and XRD analyses, it is the density of SPD-induced vacancy agglomerates which is significantly higher in FSP than in HPT (~ 10–3 instead of ~ 10–4) because of the enhanced dislocation slip activity. Thanks to their stabilization through Mg(Zn,Zr) precipitates, the vacancy agglomerates survive numerous cycles of hydrogen storage in spite of the high storage temperature of 350 °C, and can act as thermally stable heterogeneous nuclei for the hydrogenation. This latter mechanism was found in all SPD methods applied irrespective of the deformation extent, on the basis of Johnson–Mehl–Avrami-Kolmogorov analysis providing the Avrami exponent n = 1, already from the second up to the highest hydrogen storage cycles.

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Long term hydrogen storage properties of ZK60 Mg-alloy as processed by different methods of SPD

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