Abstract

Blended cements with supplementary cementitious materials (SCMs) are extensively used to mitigate the environmental impact of concrete. However, assessing their environmental performance often requires detailed data and time-intensive analyses. This study presents a machine learning-based methodology for the rapid estimation of the COQ footprint and environmental-mechanical performance (COQ/MPa ratio) of concrete mixtures using only the proportions of their main components (i.e., ordinary portland cement (OPC), SCMs, aggregates, water, and water-reducing admixtures). The models were developed using a dataset of 246 mixtures compiled from the literature and validated against 15 experimentally tested mixtures. The results demonstrate that the Gaussian Process Regressor provides the highest predictive accuracy for both COQ footprint and COQ/MPa ratio. Feature analysis revealed that OPC content has the highest impact on the COQ footprint, while aggregate fraction has the most significant influence on the COQ/MPa ratio. An optimization framework was also implemented to explore the trade-offs among mix components, showing that increasing SCM content does not always lead to improved COQ/MPa ratio, highlighting the need for balanced mixture design. The developed models offer a practical tool for supporting early-stage decision-making in construction projects by enabling rapid sustainability assessments of concrete mixtures, independent of specific SCM types, production methods, or geographical context.