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High-volume recycled glass cementitious and geopolymer composites incorporating graphene oxide

Nghia P. Tran, Tianchun Wang, Tuan Ngoc Nguyen, Hesong Jin, Tuan Ngo

2024Construction and Building Materials30 citationsDOIOpen Access PDF

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.

Topics & Concepts

GeopolymerMaterials scienceComposite materialGrapheneCementitiousOxideVolume (thermodynamics)Compressive strengthCementMetallurgyPhysicsNanotechnologyQuantum mechanicsConcrete and Cement Materials ResearchRecycling and utilization of industrial and municipal waste in materials productionMagnesium Oxide Properties and Applications
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