Optimisation of Mechanical Characteristics of Alkali-Resistant Glass Fibre Concrete towards Sustainable Construction

Concrete is a worldwide construction material, but it has inherent faults, such as low tensile strength, when not reinforced with steel or other forms of reinforcement. Various innovative materials are being incorporated into concrete to minimise its drawbacks while concurrently improving dependability and sustainability. This study addresses the research gap by exploring enhancing utilisation glass fibre (GF) concerning mechanical properties reduction embodied carbon. The most significant advantage incorporating GF capacity reduce obstruction ratio, forming clusters, subsequent material solidification. involved experiments wherein was in varying proportions 0%, 0.5%, 0.75%, 1%, 1.25%, 1.50%, 1.75%, 2% weight. Mechanical tests for durability were conducted, Embodied carbon (EC) eco-strength efficiency also evaluated assess material’s investigation found that optimal percentage be used 1.25% weight, which gives optimum results concrete’s strength UPV. Adding increases 11.76%, 17.63%, 17.73%, 5.72%, 62.5% C.S, STS, F.S, MoE, impact energy, respectively. blended value footprint associated positively correlates proportion composition. optimisation carried out utilising response surface methodology (RSM); equations generated through RSM enable computation effects concrete.