Durability, Microstructure, and Optimization of High-Strength Geopolymer Concrete Incorporating Construction and Demolition Waste

Elemam, Walid E.; Tahwia, Ahmed M.; Abdellatief, Mohamed; Youssf, Osama; Kandil, Mohamed A.

doi:10.3390/su152215832

Cited by 21 publications

(1 citation statement)

References 43 publications

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“…Geopolymer technology is expected to continue gaining popularity due to its practical and economical solutions in various applications [16,17]. Its exceptional adhesive behavior, mechanical strength, high chemical and thermal stability, and long-term robustness are all remarkable [18,19]. Moreover, due to their outstanding properties, geopolymers can possibly be utilized as warm protection materials to save energy and minimize CO 2 emissions [20].…”

Section: Introductionmentioning

confidence: 99%

Geopolymer Made from Kaolin, Diatomite, and Rice Husk Ash for Ceiling Thermal Insulation

Alvarado,

Martínez-Cerna,

Alvarado-Quintana

2023

Buildings

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In this study, geopolymers made of metakaolin (MK), diatomite (D), and rice husk ash (RHA) were developed for ceiling thermal insulation in houses to provide protection against cold temperatures. The influence of the constituent mixing ratio and the temperature of curing on the heat conductivity and compressive strength of the geopolymer was investigated. Specimens were formed according to a 10-level mix design with three replicates and subjected to curing at 40 °C and 80 °C. Heat conductivity and compressive strength were determined in accordance with established standards. The simplex lattice method was used to obtain the response surfaces, contour plots, and tracking curves. The geopolymers under study displayed a reduction in heat conductivity and an increase in compressive strength when the curing temperature was raised. The optimal mixing ratio to achieve a balance between the compressive strength and thermal conductivity of the geopolymers investigated was 0.50 MK and 0.50 RHA. Diatomite’s thermal insulation contribution is neutralized when crystals from the geopolymer gel fill the pore volume. The mixture’s optimal results were achieved when cured at 80 °C, demonstrating a thermal conductivity of 0.10 W/m·K and a compressive strength of 5.37 MPa.

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Section: Introductionmentioning

confidence: 99%

Geopolymer Made from Kaolin, Diatomite, and Rice Husk Ash for Ceiling Thermal Insulation

Alvarado,

Martínez-Cerna,

Alvarado-Quintana

2023

Buildings

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The importance of early strength in structural applications: Obsidian‐based geopolymer mortars and silica fume substitution study

Cakmak,

Ustabas,

Kurt

et al. 2024

Structural Concrete

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Geopolymer mortars, which cause less CO2 emissions than concrete and its raw material cement, are an innovative, environmentally friendly and sustainable building material. Geopolymers are formed by activating silica and alumina materials with alkaline activators. In this study, a geopolymer mortar containing obsidian (OB), also known as volcanic glass, which is free, and silica fume (SF), which is the waste material of the silicon and ferrosilicon industry, was investigated. The behavior of OB‐based geopolymer mortars under different curing times ranging from 2 to 120 h and different thermal treatment temperatures such as 90, 150, and 200°C were examined. The effectiveness of OB and SF on the physical features, compressive strength (CS), and micro‐structural of the geopolymers were characterized. Results demonstrated that the peak CSs were acquired in 96 h at 90 and 150°C heat treatment temperatures, while the highest CSs were acquired in 72 h for specimens subjected to 200°C heat treatment. Reduces in CSs were detected when the curing time exceeded the ideal limit. OB‐based geopolymer was found to be stable with SF and there was a linear relationship between SF substitution ratio and CS. The density of the mortar pieces decreased with increasing thermal curing hours. Devolving on the thermal temperature and curing time, the microstructures became more compact and microvoids and cracks decreased. It was observed that SF substitution reduced the total pore size of the geopolymers and allowed the pore structure size to be reduced. The results obtained from the study are expected to encourage the utilize of industrial wastes and new binders in the manufacture of geopolymers.

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Geopolymer concrete containing nanomaterials—a step toward sustainable construction

Indwar,

Mishra,

Titiksh

2024

Environ Sci Pollut Res

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Durability, Microstructure, and Optimization of High-Strength Geopolymer Concrete Incorporating Construction and Demolition Waste

Cited by 21 publications

References 43 publications

Geopolymer Made from Kaolin, Diatomite, and Rice Husk Ash for Ceiling Thermal Insulation

Geopolymer Made from Kaolin, Diatomite, and Rice Husk Ash for Ceiling Thermal Insulation

The importance of early strength in structural applications: Obsidian‐based geopolymer mortars and silica fume substitution study

Geopolymer concrete containing nanomaterials—a step toward sustainable construction

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