Exploring the roles of cenosphere waste in lightweight high-toughness cement-based composites under elevated temperatures: A comprehensive macro to micro analysis

Cement-based composites are prone to strength loss and cracking at high temperatures, compromising structural safety. Existing measures such as low water-cement ratios or fiber addition provide limited fire resistance, and the potential of waste derived lightweight aggregates is insufficiently understood. This study evaluates the effectiveness of cenosphere waste in improving the thermal resistance of lightweight high-toughness cement-based composites (LHTCC). LHTCC with varying cenosphere contents was exposed to 20–1000 °C and tested for physical, mechanical, and micro-structural properties using differential thermal analysis, differential scanning calorimetry, mercury intrusion porosimetry, and scanning electron microscopy. Cenosphere addition reduced cracking, mass loss, and strength degradation. Specimens with 20 % cenosphere retained 19.72 MPa compressive strength at 1000 °C, outperforming the control. Enhanced performance was attributed to increased closed porosity, fiber-melting pores relieving vapor pressure, and secondary hydration reducing Ca(OH)₂ and CaCO₃ decomposition. Cenosphere waste offers a sustainable and effective approach to enhance the fire resistance and durability of LHTCC, providing a promising solution for safer concrete structures.