High-volume recycled glass cementitious and geopolymer composites incorporating graphene oxide
Nghia P. Tran, Tianchun Wang, Tuan Ngoc Nguyen, Hesong Jin, Tuan Ngo
Abstract
This study presents the development of high-volume recycled glass construction materials using recycled glass aggregate (RGA) as a 100 % sand replacement, recycled glass powder (RGP) as 40 wt% of the binder, and 0.1 wt% graphene oxide (GO) as nano-reinforcement. The research investigates the individual and their combined effects on the engineering performance, reaction kinetics (using calorimetry, X-ray diffraction-XRD, Fourier Transform Infrared-FTIR and Thermogravimetric analysis-TGA), and microstructure (Scanning Electron Microscopy/ Energy Dispersive X-ray Spectroscopy-SEM/EDS) for both cementitious and geopolymer systems. The results indicate that while RGA reduces strength and exacerbates alkali-silica reaction (ASR), the presence of 40 wt% RGP significantly mitigates ASR despite a lower strength gain in both systems. Geopolymers exhibit significantly lower ASR expansion compared to cementitious matrices owing to their superior alkali-binding capacity and denser microstructure, which restricts water and alkali ion mobility. 0.1 wt% GO was found to accelerate geopolymerisation, enhancing the strength of geopolymer mixes, but it decreased compressive strength in cement-based mixes due to self-desiccation-induced micro-cracking under ambient curing condition. The study also highlights that cement and metasilicate, as well as slag, are the main contributors to cost and CO 2 emissions in cementitious and geopolymer systems, respectively. Overall, geopolymers exhibit a significantly lower global warming potential (< 180 kg CO 2-eq /m 3 ) compared to cement-based mixes (> 365 kg CO 2-eq /m 3 ) with a comparable cost (190–230 AUD/m 3 ). The results indicate the potential for sustainable construction applications using high volumes of recycled glass, incorporating over 70 % of the mixture by weight. • Recycled waste glass as fine aggregate and powder comprises over 70 wt% of the mixture. • Both RGP and GO demonstrate beneficial effects on ASR suppression. • Carbonation and binding capacity of gels are main factors for mitigating ASR expansion. • GO exhibits negative effects on strength of cementitious composites under ambient curing. • Geopolymers have a lower GWP per m 3 than cementitious mixes, albeit similar costs.