Skip to content

The Effect of Nano-Zinc-Oxide on Freeze-Thaw-Resistance of 3D Printed Geopolymer Mortars (2024-08)

10.1016/j.jobe.2024.110431

 Tanyildizi Harun,  Seloglu Maksut,  Coskun Ahmet
Journal Article - Journal of Building Engineering, Vol. 96, No. 110431

Abstract

The aim of this study was to investigate the freeze-thaw resistance of 3D-printed geopolymer mortars containing nano zinc oxide (nano-ZnO). Metakaolin (MK) and fly ash (FA) were selected as binders in the geopolymer mortar. The mixes containing 0 %, 0.25 %, 0.5 %, and 0.75 % nano-ZnO were prepared. The viscosity, setting time, buildability, and flow experiments were made to determine the fresh properties of the samples. Then, 40 × 40 × 160 mm samples for hardened properties were produced using the 3D printer, and they were cured at 20 ± 2 °C for 28 days. In this study, the 3D-printed geopolymer mortars were subjected to freeze-thaw cycles according to TS EN 15177 standard. Finally, ultrasonic pulse velocity (UPV), the weight change, flexural strength, and compressive strength of 3D-printed geopolymer mortar samples exposed to freeze-thaw cycles were determined. Also, the microstructure of 3D-printed geopolymer mortar samples was analyzed using X-ray diffraction (XRD), scanning electron microscopy (SEM), and energy-dispersive X-ray (EDX) analysis. This study found that the 3D-printed geopolymer mortars containing 5 % nano-ZnO had the highest resistance to freeze-thaw, with a compressive strength retention rate of 95.72 %. Thus, this study showed that the 3D-printed geopolymer mortars containing ZnO were resistant to freeze-thaw.

24 References

  1. Amran Mugahed, Abdelgader Hakim, Onaizi Ali, Fediuk Roman et al. (2021-12)
    3D Printable Alkali-Activated Concretes for Building Applications:
    A Critical Review
  2. Assaad Joseph, Hamzeh Farook, Hamad Bilal (2020-05)
    Qualitative Assessment of Interfacial Bonding in 3D Printing Concrete Exposed to Frost-Attack
  3. Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
    3D Printing Using Concrete-Extrusion:
    A Roadmap for Research
  4. Chen Wei, Pan Jinlong, Zhu Binrong, Ma XiaoMeng et al. (2023-06)
    Improving Mechanical Properties of 3D Printable One-Part Geopolymer Concrete with Steel-Fiber-Reinforcement
  5. Chen Yuxuan, Zhang Longfei, Wei Kai, Gao Huaxing et al. (2024-04)
    Rheology-Control and Shrinkage-Mitigation of 3D Printed Geopolymer Concrete Using Nano-Cellulose and Magnesium-Oxide
  6. Chougan Mehdi, Ghaffar Seyed, Jahanzat Mohammad, Albar Abdulrahman et al. (2020-04)
    The Influence of Nano-Additives in Strengthening Mechanical Performance of 3D Printed Multi-Binder Geopolymer Composites
  7. 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
  8. Jaji Mustapha, Zijl Gideon, Babafemi Adewumi (2023-08)
    Slag-Modified Fiber-Reinforced Metakaolin-Based Geopolymer for 3D Concrete Printing Application:
    Evaluating Fresh and Hardened Properties
  9. Jayathilakage Roshan, Rajeev Pathmanathan, Sanjayan Jay (2022-08)
    Rheometry for Concrete 3D Printing:
    A Review and an Experimental Comparison
  10. Kazemian Ali, Yuan Xiao, Cochran Evan, Khoshnevis Behrokh (2017-04)
    Cementitious Materials for Construction-Scale 3D Printing:
    Laboratory Testing of Fresh Printing Mixture
  11. Marchon Delphine, Kawashima Shiho, Bessaies-Bey Hela, Mantellato Sara et al. (2018-05)
    Hydration- and Rheology-Control of Concrete for Digital Fabrication:
    Potential Admixtures and Cement-Chemistry
  12. Muthukrishnan Shravan, Ramakrishnan Sayanthan, Sanjayan Jay (2021-06)
    Technologies for Improving Buildability in 3D Concrete Printing
  13. Muthukrishnan Shravan, Ramakrishnan Sayanthan, Sanjayan Jay (2023-09)
    Rapid Early-Age Strength Development of In-Line Activated Geopolymer for Concrete 3D Printing
  14. 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
  15. Panda Biranchi, Paul Suvash, Mohamed Nisar, Tay Yi et al. (2017-09)
    Measurement of Tensile Bond Strength of 3D Printed Geopolymer Mortar
  16. Panda Biranchi, Ruan Shaoqin, Unluer Cise, Tan Ming (2018-11)
    Improving the 3D Printability of High-Volume Fly-Ash Mixtures via the Use of Nano-Attapulgite-Clay
  17. Roux Charlotte, Archez Julien, Gall Corentin, Saadé Myriam et al. (2024-04)
    Towards Sustainable Material:
    Optimizing Geopolymer Mortar Formulations for 3D Printing
  18. Sheng Zhaoliang, Zhu Binrong, Cai Jingming, Li Xuesen et al. (2024-03)
    Development of a Novel Extrusion-Device to Improve the Printability of 3D Printable Geopolymer Concrete
  19. Skibicki Szymon, Jakubowska Patrycja, Kaszyńska Maria, Sibera Daniel et al. (2021-12)
    Early-Age Mechanical Properties of 3D Printed Mortar with Spent Garnet
  20. Skibicki Szymon, Pułtorak Monika, Kaszyńska Maria, Hoffmann Marcin et al. (2022-04)
    The Effect of Using Recycled PET-Aggregates on Mechanical and Durability Properties of 3D Printed Mortar
  21. Spuriņa Ella, Šinka Māris, Ziemelis Krists, Bajāre Diāna (2023-01)
    The Effects of 3D Printing on Frost-Resistance of Concrete
  22. Tran Mien, Cu Yen, Le Chau (2021-10)
    Rheology and Shrinkage of Concrete Using Polypropylene-Fiber for 3D Concrete Printing
  23. Wang Li, Xiao Wei, Wang Qiao, Jiang Hailong et al. (2022-07)
    Freeze-Thaw-Resistance of 3D Printed Composites with Desert Sand
  24. Ziada Mahmoud, Tanyildizi Harun, Seloglu Maksut, Coskun Ahmet (2024-02)
    Bacteria-Based Crack-Healing of 3D Printed PVA-Fiber-Reinforced Geopolymer Mortars

7 Citations

  1. Shilar Fatheali, Shilar Mubarakali (2025-12)
    Performance-Based Analysis of 3D Printed Geopolymers Relating Durability, Microstructure, and Life Cycle Assessment
  2. Liu Xinhao, Hu Jiajun, Xiong Guiyan, Cundy Andrew et al. (2025-12)
    Long-Term Durability and Degradation Mechanisms of 3D Printed Geopolymers (3DPG) With/Without Healing Agents in Marine Environments
  3. Safdar Gardezi Syed, Tanyildizi Harun, Haroglu Hasan, Coskun Ahmet (2025-09)
    Acid Attack Performance of 3D Printing Nano-ZnO Modified Geopolymer Mortar
  4. Liu Ruiying, Xiong Zhongming, Chen Xuan, Jia Qiong et al. (2025-09)
    Industrial Waste in 3D Printed Concrete:
    A Mechanistic Review on Rheological Control and Printability
  5. Mousavi Moein, Rangaraju Prasad (2025-09)
    Freeze-Thaw Durability of 3D Printed Concrete:
    A Comprehensive Review of Mechanisms, Materials, and Testing Strategies
  6. Tanyildizi Harun, Seloglu Maksut, Bakri Abdullah Mohd, Razak Rafiza et al. (2025-04)
    The Rheological and Mechanical Properties of 3D-Printed Geopolymers:
    A Review
  7. Tanyildizi Harun, Coskun Ahmet, Seloglu Maksut, Durmaz Taner (2025-01)
    Examination of Mechanical Properties of 3D Printed Geopolymer-Mortar Using the Taguchi -Method

BibTeX 
@article{tany_selo_cosk.2024.TEoNZOoFTRo3PGM,
  author            = "Harun Tanyildizi and Maksut Seloglu and Ahmet Coskun",
  title             = "The Effect of Nano-Zinc-Oxide on Freeze-Thaw-Resistance of 3D Printed Geopolymer Mortars",
  doi               = "10.1016/j.jobe.2024.110431",
  year              = "2024",
  journal           = "Journal of Building Engineering",
  volume            = "96",
  pages             = "110431",
}
Formatted Citation

H. Tanyildizi, M. Seloglu and A. Coskun, “The Effect of Nano-Zinc-Oxide on Freeze-Thaw-Resistance of 3D Printed Geopolymer Mortars”, Journal of Building Engineering, vol. 96, p. 110431, 2024, doi: 10.1016/j.jobe.2024.110431.

Tanyildizi, Harun, Maksut Seloglu, and Ahmet Coskun. “The Effect of Nano-Zinc-Oxide on Freeze-Thaw-Resistance of 3D Printed Geopolymer Mortars”. Journal of Building Engineering 96 (2024): 110431. https://doi.org/10.1016/j.jobe.2024.110431.