Onyelowe Kennedy C, Kamchoom Viroon, Ebid Ahmed M, Hanandeh Shadi, Llamuca Llamuca José Luis, Londo Yachambay Fabián Patricio, Allauca Palta José Luis, Vishnupriyan M, Avudaiappan Siva
Department of Civil Engineering, College of Eng & Eng Technology, Michael Okpara University of Agriculture, Umudike, Nigeria.
Department of Civil Engineering, School of Engineering and Applied Sciences, Kampala International University, Kampala, Uganda.
Sci Rep. 2025 Feb 26;15(1):6858. doi: 10.1038/s41598-025-91049-1.
The optimization of metakaolin (MK) in pre-cured geopolymer concrete involves developing predictive models to capture the interplay of various influencing factors and guide mix design for improved compressive strength and sustainability. Ensemble methods and symbolic regression are promising approaches for this task due to their complementary strengths and solving challenges associated with repeated experiments in the laboratory. Choosing machine learning predictions over repeated, expensive, and time-consuming experiments in research projects, such as optimizing the utilization of metakaolin in pre-cured geopolymer concrete, presents a paradigm shift in how data-driven insights can revolutionize material development. The integration of ensemble and symbolic regression models enables researchers to derive valuable predictions and optimize critical performance parameters efficiently. In this research work, 235 records were collected from extensive literature search for compressive strength for different mixing ratios of pre-cured metakaolin-based geopolymer concrete with concrete at different ages. Each record contains MK: The content of metakaolin (kg/m), SHS: Sodium hydroxide solution content (kg/m), SHSM: Sodium hydroxide solution molarity (Mole), SSS: Sodium silicate solution content (kg/m), W: Extra water content (not including the water in alkaline solutions) (kg/m), W/S: Water to Solid ratio (Total water content / Solid part of activator solutions + MK), NaO/AlO: Sodium oxide to aluminium oxide ratio, SiO/AlO: Silicon oxide to aluminium oxide ratio, HO/NaO: Water to Sodium oxide ratio, CA/FA: Coarse to Fine aggregate ratio, CAg: The content of coarse aggregates (kg/m), SP: The content of super-plasticizer (kg/m), PCC: 0 for no pre-curing, 1 for pre-curing at 60 °C, and 2 for pre-curing at 80 °C, CT: Curing temperature (°C), Age: The concrete age at testing (days) and CS: Compressive strength (MPa). The collected records were portioned into training set (180 records≈75%) and validation set (55 records≈ 25%) and modeled with ensemble and symbolic regression methods. At the end of the model work, performance metrics were used to evaluate the models' ability and Hoffman and Gardener's sensitivity analysis was used to evaluate the impact of the variables on the compressive strength of the pre-cured geopolymer concrete mixed with metakaolin. GB and KNN models became the decisive models with excellent performance which outclassed others and the sensitivity analysis indicated that SHSM, SSS, W/S, and NaO/AlO are the most influential to the predicted compressive strength.
偏高岭土(MK)在预制地聚合物混凝土中的优化涉及开发预测模型,以捕捉各种影响因素之间的相互作用,并指导配合比设计,从而提高抗压强度和可持续性。集成方法和符号回归是完成这项任务的有前景的方法,因为它们具有互补优势,能够解决与实验室重复实验相关的挑战。在研究项目中,如优化预制地聚合物混凝土中偏高岭土的利用,选择机器学习预测而非重复、昂贵且耗时的实验,代表了数据驱动的见解如何彻底改变材料开发的范式转变。集成模型和符号回归模型的结合使研究人员能够高效地得出有价值的预测并优化关键性能参数。在这项研究工作中,通过广泛的文献搜索,收集了235条不同龄期的预制偏高岭土地聚合物混凝土不同配合比的抗压强度记录。每条记录包含:MK:偏高岭土含量(kg/m³)、SHS:氢氧化钠溶液含量(kg/m³)、SHSM:氢氧化钠溶液摩尔浓度(摩尔)、SSS:硅酸钠溶液含量(kg/m³)、W:额外含水量(不包括碱性溶液中的水)(kg/m³)、W/S:水固比(总含水量/活性溶液+MK的固体部分)、Na₂O/Al₂O₃:氧化钠与氧化铝的比例、SiO₂/Al₂O₃:氧化硅与氧化铝的比例、H₂O/Na₂O:水与氧化钠的比例、CA/FA:粗集料与细集料的比例、CAg:粗集料含量(kg/m³)、SP:高效减水剂含量(kg/m³)、PCC:未预制为0,60°C预制为1,80°C预制为2、CT:养护温度(°C)、Age:测试时混凝土龄期(天)以及CS:抗压强度(MPa)。收集到的记录被分为训练集(180条记录≈75%)和验证集(55条记录≈25%),并采用集成方法和符号回归方法进行建模。在模型工作结束时,使用性能指标评估模型的能力,并采用霍夫曼和加德纳的敏感性分析来评估变量对掺偏高岭土的预制地聚合物混凝土抗压强度的影响。GB和KNN模型成为性能优异的决定性模型,优于其他模型,敏感性分析表明SHSM、SSS、W/S和Na₂O/Al₂O₃对预测的抗压强度影响最大。
