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HomeKey Engineering MaterialsKey Engineering Materials Vol. 1045Life Cycle Assessment of Aluminium Alloys for...

Life Cycle Assessment of Aluminium Alloys for Sustainable Building Materials and Components

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Abstract:

Aluminium has become a cornerstone of sustainable architectural design due to its lightweight properties, structural strength, corrosion resistance, and high recyclability. However, its primary production remains energy-intensive and a major contributor to greenhouse gas (GHG) emissions. This study presents a comparative Life Cycle Assessment (LCA) of commonly used aluminium alloys in architectural components, evaluating them across key stages—production and end-of-life—based on energy consumption, emissions, and recyclability. The analysis covers 3000, 5000 and 6000-series alloys, as well as recycled, anodized, and coated variants. The study contributes a parameterized LCA-based framework to support sustainable material selection in façade and structural design. It highlights the importance of incorporating recycled content, optimizing alloy use based on application, and adopting circular economy strategies such as closed-loop recycling. These findings offer practical guidance for architects, engineers, and policymakers striving toward low-carbon, net-zero building goals.

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Periodical:

Key Engineering Materials (Volume 1045)

Pages:

115-121

DOI:

https://doi.org/10.4028/p-h7wofH

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Online since:

March 2026

Authors:

Augusto Mastropasqua*, Enrico Sergio Mazzucchelli, Paolo Rigone, Sayna Hosseinzadeh Zabihi

Keywords:

Aluminium Alloys, Greenhouse Gas Emissions, Life Cycle Assessment, Recyclability, Sustainable Building Materials

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© 2026 Trans Tech Publications Ltd. All Rights Reserved

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[1] S. Shane, "Advantages and Uses of Aluminium in Construction," MACHINE MFG, 2024.

[2] J. S. Guinoa et al., "The Effects of Energy Consumption of Alumina Production in the Environmental Impacts Using Life Cycle Assessment," Int. J. Life Cycle Assess., vol. 29, p.380–393, 2024.

DOI: 10.1007/s11367-023-02257-8

[3] T. Peng et al., "Life Cycle Energy Consumption and Greenhouse Gas Emissions Analysis of Primary and Recycled Aluminum in China," Processes, vol. 10, 2022.

DOI: 10.3390/pr10112299

[4] S. Barbhuiya and B. B. Das, "Life Cycle Assessment of Construction Materials: Methodologies, Applications and Future Directions for Sustainable Decision-Making," Case Stud. Constr. Mater., vol. 19, 2023.

DOI: 10.1016/j.cscm.2023.e02326

[5] The Aluminium Association, "Aluminum's Sustainability: Infinitely Recyclable, Uniquely Sustainable," 2024.

[6] J. Wang, The Environmental Footprint of Semi-Fabricated Aluminum Products in North America: A Life Cycle Assessment Report, The Aluminum Association, 2022.

[7] P. Nunez and S. Jones, "Cradle-to-Gate: Life Cycle Impact of Primary Aluminium Production," Int. J. Life Cycle Assess., vol. 21, p.1594–1604, 2016.

DOI: 10.1007/s11367-015-1003-7

[8] J. Abdollahi et al., "Environmental Impact Assessment of Aluminium Production Using Life Cycle Assessment and Multicriteria Analysis," Environ. Sci. Toxicol., 2021.

[9] S. Kamalakkannan and A. K. Kulatunga, "Optimization of Eco-Design Decisions Using a Parametric Life Cycle Assessment," Sustain. Prod. Consum., vol. 27, p.1297–1316, 2021.

DOI: 10.1016/j.spc.2021.03.006

[10] S. Carlisle et al., "Aluminium and Life Cycle Thinking Towards Sustainable Cities," World Aluminium, Int. Aluminium Institute, 2015.

[11] J. Atherton, "Declaration by the Metals Industry on Recycling Principles," Int. J. Life Cycle Assess., vol. 12, no. 1, p.59–60, 2007.

DOI: 10.1065/lca2006.11.283

[12] J. Van Houwelingen et al., A Collection of Aluminium from Buildings in Europe, Delft Univ. of Technology, European Aluminium Association, 2004.

[13] U.S. Dept. of Energy, U.S. Energy Requirements for Aluminum Production: Historical Perspective, Theoretical Limits and Current Practices, 2007.

DOI: 10.2172/1216245

[14] Int. Aluminium Institute, "Aluminium Recycling Saves 95% of the Energy Needed for Primary Aluminium Production," 2024.

[15] S. Shane, "Hard Anodizing of Aluminium Alloys: Benefits and Applications," M. MFG, 2024.

[16] Int. Aluminium Institute, "Aluminium Sector Greenhouse Gas Emissions for 2023," 2024.

[17] S. Al-Alimi et al., "Recycling Aluminium for Sustainable Development: A Review of Different Processing Technologies in Green Manufacturing," Results Eng., vol. 23, 2024.

[18] T. Wang et al., "Upcycled High-Strength Aluminum Alloys from Scrap Through Solid-Phase Alloying," Nat. Commun., 2024.

DOI: 10.1038/s41467-024-53062-2

[19] Fairview Architectural, "Which Aluminum Alloy Is Right for Your Project?," 2023.

[20] Lasered Components, "Famous Aluminium Structures," 2024.

[21] E. Baldwin, "Soda Pop Design: 7 Clever Architectural Details in Aluminum," Architizer, 2024.

[22] Taber Extrusions, "6000 Series Aluminum Alloys," 2024.

[23] All Weather Architectural Aluminium, "Connecticut Gallery," 2024.

[24] S. Bruschi et al., "Machinability of Recycled Aluminum Alloys," Manuf. Lett., vol. 41, p.1669–1675, 2024.

[25] Hydro, "I Hope the Industry Discovers the Untapped Potential of Recycled Aluminium," 2020.

[26] Building Enclosure, "Anodized Aluminum Unique Panels Used on Shopping Complex," 2020.

[27] Aluminum Stock, "Exploring the Benefits of Using 3000 Series Aluminum in Manufacturing," 2024.

[28] E. Kimiya, "A Deep Dive into 5000-Series Aluminum Ingots: Strength, Weldability, and Uses," EMK, 2024.

[29] Int. Aluminium Institute, Global Aluminium Recycling: A Cornerstone of Sustainable Development, 2009.

[30] F. Saldanha et al., "Evaluation of 6000 Al Alloys for Application in Chassis of Electric Vehicles," Mater. Res., vol. 25, no. 4, 2022.

[31] ESAB, "Heat-Treatable vs Non-Heat-Treatable Aluminum Alloys," 2021.

[32] D. De Caro et al., "Effect of Recycling on the Mechanical Properties of 6000 Series Aluminum-Alloy Sheet," Materials, 2023.

[33] Novelis, "Top Five Sustainable Attributes of Aluminum," 2024.

[34] Zheng Ji Aluminum, "Complete Guide to Hard Anodizing for Aluminum," 2024.

[35] Alueuropa, "Aluminum is Among the Most Recyclable Materials in the World (95% Recovery Rate)," 2024.

[36] D. Manney, "Powder Coating's Environmental Impact Compared to Wet Paint," CWF, 2024.

[37] Covestro, Carbon Footprint Study: Industrial Coatings on Metal Substrate, 2021.

[38] Shaping Powder, DSM Carbon Footprint Study for Industrial Coatings on Metal Substrate, 2021.

[39] KMH Sustainable Infrastructure, Environmental Impact Comparison of Fluoropolymer Powder Coating and Anodising Processes, 2010.