Abstract
Against the backdrop of dual-carbon goals and resource constraints, the high-value utilization of recycled fine aggregates (RFAs) remains limited, leading to inconsistent engineering performance and insufficient durability. Enzyme-induced carbonate precipitation (EICP) represents a promising low-carbon cementation method, yet its deposition uniformity and cementation efficiency are influenced by the pore structure of granular media and associated mass transfer pathways. This study employs a two-stage experimental design to investigate the synergistic effects of particle size distribution characteristics, represented primarily by d(50), and fiber addition on EICP-cemented RFA. Phase I (fiber-free; d(50) = 0.67-1.14 mm) results indicate that, across the tested gradation schemes, the CaCO(3) content generally decreased from 9.49% to 7.72% as the representative d(50) increased, while the dry density changed only slightly (1.637-1.617 g/cm(3)). However, the unconfined compressive strength (UCS) decreased from 1000 kPa to 541 kPa (45.9% reduction), indicating that strength is primarily governed by the connectivity of the cementation network rather than solely by the degree of densification. In Phase II, glass fiber (GF), polypropylene fiber (PPF), and jute fiber (JF) were incorporated into the ERFA4 gradation scheme selected for fiber modification. All three systems exhibited a unimodal optimum pattern: the peak CaCO(3) contents reached 10.71% (GF 0.5%), 10.11% (PPF 0.7%), and 11.46% (JF 0.7%), corresponding to peak UCS values of 1917, 1874, and 2450 kPa, respectively. Microscopic analysis suggested that fiber bridging coupled with CaCO(3) deposition may contribute to the formation of a "fiber-CaCO(3)-particle" stress-transfer network, which is consistent with the observed enhancements in load-bearing capacity, ductility, and post-peak stability.