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3D Printing of Recycled Materials for Sustainable Construction (2025-07)

A Comprehensive Economic and Life Cycle Assessment

10.1016/j.rser.2025.116059

 Raza Muhammad,  Kravchenko Ekaterina,  Besklubova Svetlana, Lazorenko Georgy, Markelow Maxim, Kasprzhitskii Anton,  Zhong Ray
Journal Article - Renewable and Sustainable Energy Reviews, Vol. 223, No. 116059

Abstract

The demand for sustainable materials and technologies has risen due to the construction sector's substantial impact on the ecosystem, natural resources and human health. Therefore, this study aims to investigate the sustainability potential of recycled materials for the construction 3D printing (3DP) process. Mortar mixtures are designed using recycled binder materials (fly ash and blast furnace slag) and aggregate materials (waste concrete-based recycled fine aggregate (RFA)) for the 3D printing process. The adequacy of different geopolymer mixtures for the printing process is assessed through the open time, slump and spread diameter. The results showed that geopolymer mixtures containing RFA offered adequate fresh properties and more dimensional stability for the 3D printing process. The compression testing of the RFA-based geopolymers (along with different testing orientations) also yields better strength than the natural fine aggregate (NFA) in 3D printing. Apart from lab-scale experimentation, a case study of 3D printed and casted walls (using NFA and RFA based geopolymer mixtures) has been considered for comprehensive economic and life cycle analysis (LCA). The results showed that the 3D printed wall using RFA offered a lower burden on the ecosystem, natural resources, and human health; moreover, the lowest cost was observed in the case of the 3D printed wall containing RFA. The higher overall environmental and economic impact of casted wall was primarily due to the usage of plywood formwork. Sensitivity analysis showed that reusing formwork up to 10 times can potentially reduce economic and ecological burdens, depending on construction complexity, but still, traditional construction's overall burden remains higher than 3D printing. As 3D printing technology matures and economies of scale are realized, 3D printing is expected to reduce costs and environmental impacts further.

35 References

  1. Alhumayani Hashem, Gomaa Mohamed, Soebarto Veronica, Jabi Wassim (2020-06)
    Environmental Assessment of Large-Scale 3D Printing in Construction:
    A Comparative Study between Cob and Concrete
  2. Anton Ana-Maria, Reiter Lex, Wangler Timothy, Frangez Valens et al. (2020-12)
    A 3D Concrete Printing Prefabrication Platform for Bespoke Columns
  3. Babafemi Adewumi, Kolawole John, Miah Md, Paul Suvash et al. (2021-06)
    A Concise Review on Inter-Layer Bond Strength in 3D Concrete Printing
  4. Bai Gang, Wang Li, Ma Guowei, Sanjayan Jay et al. (2021-03)
    3D Printing Eco-Friendly Concrete Containing Under-Utilised and Waste Solids as Aggregates
  5. Besklubova Svetlana, Raza Muhammad, Zhong Ray, Skibniewski Mirosław (2024-06)
    3D Printing vs. Traditional Construction:
    Cost Comparisons from Design to Waste Disposal Stages
  6. Cavalcante Tiago, Toledo Filho Romildo, Mendoza Reales Oscar (2025-04)
    Rheological and Environmental Implications of Recycled Concrete Powder as Filler in Concrete 3D Printing
  7. Christen Heidi, Zijl Gideon, Villiers Wibke (2022-05)
    The Incorporation of Recycled Brick-Aggregate in 3D Printed Concrete
  8. Ding Tao, Xiao Jianzhuang, Qin Fei, Duan Zhenhua (2020-03)
    Mechanical Behavior of 3D Printed Mortar with Recycled Sand at Early-Ages
  9. Han Yilong, Yang Zhihan, Ding Tao, Xiao Jianzhuang (2020-08)
    Environmental and Economic Assessment on 3D Printed Buildings with Recycled Concrete
  10. Hou Shaodan, Duan Zhenhua, Ye Taohua, Zou Shuai et al. (2023-06)
    Mechanical Properties and Pore-Structure of 3D Printed Mortar with Recycled Powder
  11. İlcan Hüseyin, Şahin Oğuzhan, Kul Anil, Yıldırım Gürkan et al. (2022-03)
    Rheological Properties and Compressive Strength of Construction and Demolition Waste-Based Geopolymer Mortars for 3D Printing
  12. Jia Lutao, Niu Geng, Dong Enlai, Jiang Yifan et al. (2024-08)
    Optimization-Strategy for Incorporating Recycled Brick-Powder in 3D Printed Concrete by Balancing Low-Carbon Footprint and Enhanced Performance
  13. Khan Shoukat, Jassim Muhammad, İlcan Hüseyin, Şahin Oğuzhan et al. (2023-04)
    3D Printing of Circular Materials:
    Comparative Environmental Analysis of Materials and Construction Techniques
  14. Liu Huawei, Liu Chao, Wu Yiwen, Bai Guoliang et al. (2022-06)
    Hardened Properties of 3D Printed Concrete with Recycled Coarse Aggregate
  15. Liu Siyu, Lu Bing, Li Hongliang, Pan Zehua et al. (2022-03)
    A Comparative Study on Environmental Performance of 3D Printing and Conventional Casting of Concrete Products with Industrial Wastes
  16. Liu Junli, Setunge Sujeeva, Tran Jonathan (2022-07)
    3D Concrete Printing with Cement-Coated Recycled Crumb Rubber:
    Compressive and Microstructural Properties
  17. Liu Chao, Wang Zhihui, Wu Yiwen, Liu Huawei et al. (2023-02)
    3D Printing Concrete with Recycled Sand:
    The Influence Mechanism of Extruded Pore-Defects on Constitutive Relationship
  18. Lu Bing, Zhu Weiping, Weng Yiwei, Liu Zhixin et al. (2020-02)
    Study of MgO-Activated-Slag as a Cementless Material for Sustainable Spray-Based 3D Printing
  19. Nematollahi Behzad, Vijay Praful, Sanjayan Jay, Nazari Ali et al. (2018-11)
    Effect of Polypropylene Fiber Addition on Properties of Geopolymers Made by 3D Printing for Digital Construction
  20. Nuh Mishael, Oval Robin, Orr John, Shepherd Paul (2022-09)
    Digital Fabrication of Ribbed Concrete Shells Using Automated Robotic Concrete Spraying
  21. Pasupathy Kirubajiny, Ramakrishnan Sayanthan, Sanjayan Jay (2023-01)
    3D Concrete Printing of Eco-Friendly Geopolymer Containing Brick Waste
  22. Pessoa Ana Sofia, Guimarães Ana, Lucas Sandra, Simões Nuno (2021-02)
    3D Printing in the Construction Industry:
    A Systematic Review of the Thermal Performance in Buildings
  23. Rahul Attupurathu, Mohan Manu, Schutter Geert, Tittelboom Kim (2021-10)
    3D Printable Concrete with Natural and Recycled Coarse Aggregates:
    Rheological, Mechanical and Shrinkage Behavior
  24. Ramakrishnan Sayanthan, Pasupathy Kirubajiny, Mechtcherine Viktor, Sanjayan Jay (2024-05)
    Print-Head Mixing of Geopolymer and OPC Slurries for Hybrid Alkali-Activated Cement in 3D Concrete Printing
  25. Raza Muhammad, Besklubova Svetlana, Zhong Ray (2024-11)
    Comparative Environmental Value-Stream-Assessment of Off-Site and On-Site 3D Construction Printing Processes
  26. Raza Muhammad, Zhong Ray (2022-08)
    A Sustainable Roadmap for Additive Manufacturing Using Geopolymers in Construction Industry
  27. Robayo-Salazar Rafael, Vargas Armando, Martínez Fabio, Gutiérrez Ruby (2024-02)
    Utilization of Powders and Fine Aggregates from the Recycling of Construction and Demolition Waste in the 3D Printing of Portland-Based Cementitious Materials
  28. Şahin Oğuzhan, İlcan Hüseyin, Ateşli Anıl, Kul Anil et al. (2021-05)
    Construction and Demolition Waste-Based Geopolymers Suited for Use in 3D Additive Manufacturing
  29. Sambucci Matteo, Valente Marco (2021-06)
    Influence of Waste-Tire-Rubber-Particles-Size on the Microstructural, Mechanical, and Acoustic Insulation Properties of 3D Printable Cement Mortars
  30. Sanjayan Jay, Nematollahi Behzad, Xia Ming, Marchment Taylor (2018-04)
    Effect of Surface Moisture on Inter-Layer Strength of 3D Printed Concrete
  31. Sanjayan Jay, Nematollahi Behzad, Xia Ming, Marchment Taylor (2021-06)
    Effect of Surface Moisture on Inter-Layer Strength of 3D Printed Concrete:
    Correction
  32. Skibicki Szymon, Federowicz Karol, Hoffmann Marcin, Chougan Mehdi et al. (2024-05)
    Potential of Reusing 3D Printed Concrete (3DPC) Fine Recycled Aggregates as a Strategy Towards Decreasing Cement Content in 3DPC
  33. Ting Guan, Tay Yi, Qian Ye, Tan Ming (2019-03)
    Utilization of Recycled Glass for 3D Concrete Printing:
    Rheological and Mechanical Properties
  34. Xiao Jianzhuang, Zou Shuai, Yu Ying, Wang Yu et al. (2020-09)
    3D Recycled Mortar Printing:
    System-Development, Process-Design, Material-Properties and On-Site-Printing
  35. Yoris-Nobile Adrian, Lizasoain-Arteaga Esther, Slebi-Acevedo Carlos, Blanco-Fernandez Elena et al. (2022-07)
    Life-Cycle-Assessment and Multi-Criteria Decision-Making-Analysis to Determine the Performance of 3D Printed Cement Mortars and Geopolymers

2 Citations

  1. Mu Xiaoshao, Zhang Xiaoling, He Gang, Liew Kim (2026-01)
    Toward Low-Carbon 3D Concrete Printing Through Circular Construction and Waste Valorization
  2. Shilar Fatheali, Shilar Mubarakali (2025-12)
    Performance-Based Analysis of 3D Printed Geopolymers Relating Durability, Microstructure, and Life Cycle Assessment

BibTeX 
@article{raza_krav_besk_lazo.2025.3PoRMfSC,
  author            = "Muhammad Huzaifa Raza and Ekaterina Kravchenko and Svetlana Besklubova and Georgy Lazorenko and Maxim Markelow and Anton Kasprzhitskii and Ray Y. Zhong",
  title             = "3D Printing of Recycled Materials for Sustainable Construction: A Comprehensive Economic and Life Cycle Assessment",
  doi               = "10.1016/j.rser.2025.116059",
  year              = "2025",
  journal           = "Renewable and Sustainable Energy Reviews",
  volume            = "223",
  pages             = "116059",
}
Formatted Citation

M. H. Raza, “3D Printing of Recycled Materials for Sustainable Construction: A Comprehensive Economic and Life Cycle Assessment”, Renewable and Sustainable Energy Reviews, vol. 223, p. 116059, 2025, doi: 10.1016/j.rser.2025.116059.

Raza, Muhammad Huzaifa, Ekaterina Kravchenko, Svetlana Besklubova, Georgy Lazorenko, Maxim Markelow, Anton Kasprzhitskii, and Ray Y. Zhong. “3D Printing of Recycled Materials for Sustainable Construction: A Comprehensive Economic and Life Cycle Assessment”. Renewable and Sustainable Energy Reviews 223 (2025): 116059. https://doi.org/10.1016/j.rser.2025.116059.