Modular multi-domain AI framework for sustainable construction material optimisation
The construction sector is a major contributor to global environmental impacts, largely driven by the embodied emissions of structural materials. Early-stage material selection therefore represents a critical opportunity for impact reduction; however, conventional life-cycle assessment (LCA) approaches remain limited in systematically evaluating large numbers of feasible material configurations under multiple and often conflicting sustainability criteria, constraining effective decision-making during design. To address this limitation, this study develops an artificial intelligence–driven decision-support framework for the systematic exploration and optimisation of construction material configurations within a fixed building design. The framework integrates LCA modelling, scenario-based material substitution, predictive modelling using mixture-of-experts backpropagation neural networks, and sustainability-oriented optimisation within a unified workflow. A reinforced-concrete office building in the United Kingdom is used as a case study to generate 1500 technically feasible material scenarios by varying concrete compositions (including GGBS and fly ash substitution), reinforcement steel production routes, cement formulations, and end-of-life pathways. Scenario outputs from OneClick LCA are used to train the predictive models, enabling rapid estimation of multiple sustainability indicators, which are subsequently coupled with a shuffled frog leaping optimisation algorithm using a composite sustainability index. The results demonstrate that the framework efficiently identifies material configurations that balance environmental, circularity, and cost-related performance while expanding the range of feasible design solutions beyond conventional scenario-based evaluation. The proposed framework provides a scalable and flexible decision-support tool for early-stage design, enabling systematic assessment of trade-offs and supporting informed material selection under practical design and feasibility constraints.
| Item Type | Article |
|---|---|
| Identification Number | 10.1016/j.eiar.2026.108582 |
| Additional information | © 2026 The Author(s). Published by Elsevier Inc. This is an open access article under the CC BY license ( http://creativecommons.org/licenses/by/4.0/ ). |
| Date Deposited | 30 Jun 2026 07:24 |
| Last Modified | 04 Jul 2026 01:09 |
