Журналы →  Non-ferrous Мetals →  2024 →  №1 →  Назад

MATERIALS SCIENCE
Название Composition and stability of Al2(Mg,Ca) compound in alloys of Al – Mg – Ca – (Zn) system
DOI 10.17580/nfm.2024.01.08
Автор Doroshenko V. V., Korotkova N. O., Cherkasov S. O., Kalitina M. N.
Информация об авторе

Moscow Polytechnic University (Moscow Polytech), Moscow, Russia

V. V. Doroshenko, Candidate of Technical Sciences, Senior Researcher of the Department “Materials Science”, Associate Professor of the Project Activity Sector, e-mail: v.doroshenko@mail.ru

M. N. Kalitina, Lecturer of the Department “Foreign Language”, e-mail: 040320011968@mail.ru

 

National Research Technological University “MISIS”, Moscow, Russia
N. O. Korotkova, Candidate of Technical Sciences, Junior Researcher of the Laboratory “Hybrid Nanostructured Materials”, e-mail: darkhopex@mail.ru
S. O. Cherkasov, Post-Graduate Student of the Department “Metal Forming”, e-mail: ch3rkasov@gmail.com

Реферат

Alloys based on the Al – Mg – Ca – (Zn) system may be attractive as a class of low-density aluminum alloys combining strength, technological effectiveness and lightness. With a minimum proportion of zinc, magnesium plays the main role in strengthening, which should be maximally included in the composition of an aluminum (Al)-based solid solution. Therefore, compounds that pull magnesium from (Al) can lead to a decrease in the strength of the alloy. Such a compound is the phase described by the formula Al2(Mg,Ca) and previously undetectable in alloys of the Al – Mg – Ca – (Zn) system. The aim of the work was to determine the magnesium concentrations at which this compound was detected, to study its stoichiometric composition, stability during heat treatment and to determine the temperature range of its formation. The solution of these problems was implemented using optical (OM) and scanning microscopy (SEM) techniques, thermal analysis and the CALPHAD computational approach. Al2(Mg,Ca) was determined to be present in alloys containing 3–6% magnesium and 4% calcium, and changes its stoichiometric composition inversely depending on the magnesium content: with the decrease of magnesium, its share in the compound increases. The classical heat treatment for magnals has no effect on the chemical composition of the phase, and it remains stable. A temperature range was identified in the Al4%Mg8%Ca alloy when the formation of the compound of interest was detected. The alleged nature of its occurrence is described by the eutectic reaction L → (Al) + Al2(Mg,Ca). At the same time, the actual data of the thermal analysis have good convergence with the calculated values.

The research was carried out at the expense of the grant of the Russian Science Foundation No. 23-79-01055 (optical and scanning microscopy, thermal analysis) and the funds of the P.L. Kapitsa grant of the Moscow Polytechnic University, implemented within the framework of the Priority 2030 program (melting and casting, heat treatment).

Ключевые слова Aluminium, magnesium, calcium, compounds, microstructure, crystallization
Библиографический список

1. Wahid M. A., Siddiquee A. N., Khan Z. A. Aluminum Alloys in Marine Construction: Characteristics, Application, and Problems from a Fabrication Viewpoint. Marine Systems & Ocean Technology. 2020. Vol. 15. pp. 70–80.
2. Wang B., Zhang Zh., Xu G., Zeng X., Hu W., Matsubae K. Wrought and Cast Aluminum Flows in China in the Context of Electric Vehicle Diffusion and Automotive Lightweighting. Resources, Conservation and Recycling. 2023. Vol. 191. 106877.
3. Pozdniakov A. V., Yarasu V., Barkov R. Yu., Yakovtseva O. A., Makhov S. V., Napalkov V. I. Microstructure and
Mechanical Properties of Novel Al – Mg – Mn – Zr – Sc – Er alloy. Materials Letters. 2017. Vol. 202. pp. 116–119.
4. Korotkova N. O., Cherkasov S. O., Aksenov A. A., Timofeev V. N. Structure and Properties of the Al – 1% Ca – 0.5% Fe – 0.25% Si – 0.5% Zr Alloy Produced via Casting in an Electromagnetic Crystallizer. Fizika Metallov i Metallovedenie. 2021. Vol. 122, Iss. 7. pp. 776–782.
5. Letyagin N. V., Akopyan T. К., Sokorev A. A., Tsydenov A. G., Musin A. F., Palkin P. A. Structure and Properties of Coatings Formed on Cast Al – Ca Alloys by Plasma Electrolytic Oxidation. Metallurgist. 2024. Vol. 67. pp. 1473–1481.
6. Letyagin N. V., Akopyan T. К., Sokorev A.A., Tsydenov A. G. Plasma Electrolytic Oxidation of Aluminum-Calcium Binary Alloys in a Cast Condition. Metallurgist. 2024. Vol. 67. pp. 1325–1333.
7. Belov N. A., Akopyan T. K., Naumova E. A., Doroshenko V. V., Sviridova T. A., Korotkova N. O. Formation and Characterization of Al10CaFe2 Compound in Al – Ca – Fe Alloys. Transactions of Nonferrous Metals Society of China. 2024. Vol. 34, Iss. 2. pp. 361–377.
8. Shen T., Zhang S., Liu Z., Yu S., Jiang J., Tao X., Akopyan T., Belov N., Yao Z. Convert Harm into Benefit: The Role of the Al10CaFe2 Phase in Al – Ca Wrought Aluminum Alloys Having High Compatibility with Fe. Materials. 2023. No. 16. 7488.
9. Akopyan T. K., Belov N. A., Letyagin N. V., Cherkasov S. O., Nguen X. D. Description of the New Eutectic Al – Ca – Cu System in the Aluminum Corner. Metals. 2023. No. 13. 802.
10. Belov N. A., Naumova E. A., Bazlova T. A., Doroshenko V. V. Phase Composition and Hardening of Castable Al – Ca – Ni – Sc Alloys Containing 0.3% Sc. Metal Science and Heat Treatment. 2017. Vol. 59. pp. 76–81.
11. Akopyan T. K., Belov N. A., Naumova E. A., Letyagin N. V., Sviridova T. A. Al-Matrix Composite Based on Al – Ca – Ni – La System Additionally Reinforced by L12 Type Nanoparticles. Transactions of Nonferrous Metals Society of China. 2020. Vol. 30, Iss. 4. pp. 850–862.
12. Karpova Zh. A., Shurkin P. K., Sivtsov K. I., Laptev I. N. Structure formation and processability of the Al – Zn – Mg – Ca – Fe – Zr – Sc alloy at hot rolling and TIG welding. Izvestiya Vuzov. Tsvetnaya Metallurgiya. 2021. Iss. 3. pp. 46–56.
13. Belov N., Naumova E., Akopyan T. Eutectic Alloys Based on the Al – Zn – Mg – Ca System: Microstructure, Phase Composition and Hardening. Materials Science and Technology. 2017. Vol. 33, Iss. 6. pp. 656–666.
14. Belov N. A., Bazlova T. A., Alekseeva E. V., Naumova E. A. Structure, Phase Composition, and Strengthening of Cast Al – Ca – Mg – Sc Alloys. Fizika Metallov i Metallovedenie. 2016. Vol. 117, Iss. 2. p. 208.
15. Doroshenko V. V., Barykin M. A., Korotkova N. O., Vasina M. A. The Effect of Calcium and Zinc on the Structure and Phase Composition of Casting Aluminum–Magnesium Alloys. Fizika Metallov i Metallovedenie. 2022. Vol. 123, Iss. 8. pp. 872–880.
16. Doroshenko V., Shurkin P., Sviridova T., Fortuna A., Shkaley I. Phase Composition and Microstructure of Cast Al – 6%Mg – 2%Ca – 2%Zn Alloy with Fe and Si Additions. Metals. 2023. No. 13. 1584.
17. Jeong H. T., Han S. H., Kim W. J. Effects of Large Amounts of Mg (5–13 wt%) on Hot Compressive Deformation Behavior and Processing Maps of Al – Mg Alloys. Journal of Alloys and Compounds. 2019. Vol. 788. pp. 1282–1299.
18. Thermo-Calc Software TTAL5 Al-Alloys. URL: www.thermocalc.com (Accessed Date: 07.06.24).
19. Zhang Sh., Du H., Yao Zh., Liu Z., Zhu Y., Shuai L., Huang T., Huang X., Tao X., Mondal D.P., Akopyan T., Belov N. Superior High Temperature Creep Resistance of a Cast Al – Mg – Ca – Sc Alloy with Multi-Scale Hierarchical Microstructures. Materials Science and Engineering: A. 2022. Vol. 850. 143533.

Полный текст статьи Composition and stability of Al2(Mg,Ca) compound in alloys of Al – Mg – Ca – (Zn) system
Назад