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Cementless Aggregate From Industrial Solid Wastes: Optimization Preparation and Environmental Impact Assessment

Author

Listed:
  • Xiangbo Zou
  • Kai Xiong
  • Wei Zhao
  • Yafang Li
  • Dequn Ma
  • Chuangting Chen
  • Zhenwei Yi
  • Tao Wang

Abstract

To address the issues of high density and low strength in traditional non‐fired lightweight aggregates, using CO2 mineralization curing can effectively enhance product performance and synergistically utilize industrial solid waste and CO2. CO2 mineralization curing significantly improves the cylindrical compressive strength of lightweight aggregates (6.8 MPa), reduces the water absorption rate (6.83%), and achieves a suitable bulk density (896 kg/m3). By analyzing the carbonation rate of different particle sizes through gas–solid reaction kinetics, it was found that the rate curve of mineralization curing for lightweight aggregate samples better fits the three‐dimensional diffusion model, with smaller particles exhibiting a higher carbonation rate. Microscopic characterization analysis revealed that the primary mineralization product is calcium carbonate, which is present in the form of calcite. Higher curing temperatures and prolonged durations may result in decalcification within the lightweight aggregates. Moreover, the calcium carbonate particles produced during the carbonation process can cause expansion of the internal structure of the lightweight aggregates, leading to a decline in the mechanical properties of the product. The life cycle carbon emissions for each ton of steam‐cured lightweight aggregate are 105.821 kg, whereas the life cycle carbon emissions for CO2 mineralized lightweight aggregates are only −1.879 kg, making this method beneficial for clean production and solving significant problems in actual production. © 2025 Society of Chemical Industry and John Wiley & Sons, Ltd.

Suggested Citation

  • Xiangbo Zou & Kai Xiong & Wei Zhao & Yafang Li & Dequn Ma & Chuangting Chen & Zhenwei Yi & Tao Wang, 2025. "Cementless Aggregate From Industrial Solid Wastes: Optimization Preparation and Environmental Impact Assessment," Greenhouse Gases: Science and Technology, Blackwell Publishing, vol. 15(3), pages 305-318, June.
  • Handle: RePEc:wly:greenh:v:15:y:2025:i:3:p:305-318
    DOI: 10.1002/ghg.2336
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    1. Shu-Yuan Pan & Yi-Hung Chen & Liang-Shih Fan & Hyunook Kim & Xiang Gao & Tung-Chai Ling & Pen-Chi Chiang & Si-Lu Pei & Guowei Gu, 2020. "CO2 mineralization and utilization by alkaline solid wastes for potential carbon reduction," Nature Sustainability, Nature, vol. 3(5), pages 399-405, May.
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