Geopolymer: A Review of Structure, Applications and Properties of Fiber Reinforced Composites

Grance, Ellen Guimarães Oliveira; Paiva, Maria das Dores Macedo; Souza, Fernando Gomes de; Filho, Romildo Dias Tolêdo

doi:10.31031/rdms.2018.07.000666

Cited by 3 publications

(1 citation statement)

References 46 publications

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“…Geopolymers have demonstrated their versatility across a wide range of applications, spanning from fire-resistant materials to decorative stone creations, thermal insulation, eco-friendly building materials, energy-efficient ceramic tiles, refractory products, materials resistant to thermal shocks, biotechnology, foundry industry, cement, and concrete. They also find utility in composite materials for infrastructure repair and reinforcement, advanced composites for enhancing aircraft interiors and automotive components, cutting-edge resin systems, containment of radioactive and hazardous waste, artistic and decorative projects, preservation of cultural heritage, archaeological endeavours, and contributions to the history of science [11]. The development of geopolymer is a promising step towards a more sustainable construction industry.…”

Section: Introductionmentioning

confidence: 99%

Exploring Tanzanian Clay Minerals as Promising Candidates for Geopolymer Cement: A Sustainable Approach to Climate-Friendly Cement

Kitalika,

Mabeyo,

Mushi

et al. 2024

Preprint

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The quest for sustainable construction materials has sparked interest in geopolymers as eco-friendly alternatives to traditional Portland cement. In response to this endeavour, this study explored Tanzanian clay minerals collected from different regions to assess their potential as candidate materials for geopolymer cement. The XRF results revealed varying elemental compositions that are crucial for geopolymer production. Essential components like SiO2 and Al2O3 were found, with some regions showing balanced ratios suitable for geopolymer cement. Minor Fe2O3 content was also detected, which could enhance material strength by forming iron silicate binders. Limited CaO content was noted, which can be beneficial in influencing geopolymer properties. However, high CaO levels in a few regions of the Eastern zone may be less suitable for geopolymer cement production. Most samples showed minimal Loss of Ignition (LOI), indicating their potential to enhance the workability of geopolymers. The study identified specific regions with clays suitable for various high-technology geopolymer resins, low-CO2 geopolymer cement, and specialized applications, though beneficiation might sometimes be required. The XRD results of clay samples revealed varying mineral compositions, with quartz being the dominant mineral in several samples, indicating high silica content. These mineralogical findings align with the XRF results, reinforcing the presence of essential elements for geopolymer cement development. The SEM-EDS results further verified the elemental composition of select samples. Additionally, TGA results provided insights into the thermal stability of the clay samples, confirming their suitability for geopolymer cement production. These results demonstrated that Tanzanian clay minerals are well-suited for producing eco-friendly cement. By leveraging these readily available local clay resources and unlocking their potential for sustainable construction materials, this research significantly advances the worldwide endeavour to mitigate the environmental footprint of the construction sector while advocating for eco-conscious alternatives to conventional Portland cement.

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Section: Introductionmentioning

confidence: 99%

Exploring Tanzanian Clay Minerals as Promising Candidates for Geopolymer Cement: A Sustainable Approach to Climate-Friendly Cement

Kitalika,

Mabeyo,

Mushi

et al. 2024

Preprint

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Biodiesel Synthesis Using Magnetizable Geopolymer as Heterogeneous Catalysts Nanocomposite Assisted by Artificial Intelligence

Brandão,

de Souza,

Maranhão

et al. 2024

Top Catal

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A Review of Sisal Fiber-Reinforced Geopolymers: Preparation, Microstructure, and Mechanical Properties

Qu,

Niu,

et al. 2024

Molecules

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The early strength of geopolymers (GPs) and their composites is higher, and the hardening speed is faster than that of ordinary cementitious materials. Due to their wide source of raw materials, low energy consumption in the production process, and lower emissions of pollutants, they are considered to have the most potential to replace ordinary Portland cement. However, similar to other inorganic materials, the GPs themselves have weak flexural and tensile strength and are sensitive to micro-cracks. Improving the toughness of GP materials can be achieved by adding an appropriate amount of fiber materials into the matrix. The use of discrete staple fibers shows great potential in improving the toughness of GPs. Sisal is a natural fiber that is reproducible and easy to obtain. Due to its good mechanical properties, low cost, and low carbon energy usage, sisal fiber (SF) is a GP composite reinforcement with potential development. In this paper, the research progress on the effect of SF on the properties of GP composites in recent decades is reviewed. It mainly includes the chemical composition and physical properties of SFs, the preparation technology of sisal-reinforced geopolymers (SFRGs), the microstructure analysis of the interface of SFs and the GP matrix, and the macroscopic mechanical properties of SFRGs. The properties of SFs make them have good bonding properties with the GP matrix. The addition of SFs can improve the flexural strength and tensile strength of GP composites, and SFRGs have good engineering application prospects.

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Geopolymer: A Review of Structure, Applications and Properties of Fiber Reinforced Composites

Cited by 3 publications

References 46 publications

Exploring Tanzanian Clay Minerals as Promising Candidates for Geopolymer Cement: A Sustainable Approach to Climate-Friendly Cement

Exploring Tanzanian Clay Minerals as Promising Candidates for Geopolymer Cement: A Sustainable Approach to Climate-Friendly Cement

Biodiesel Synthesis Using Magnetizable Geopolymer as Heterogeneous Catalysts Nanocomposite Assisted by Artificial Intelligence

A Review of Sisal Fiber-Reinforced Geopolymers: Preparation, Microstructure, and Mechanical Properties

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