Effect of Na2CO3 Replacement Quantity and Activator Modulus on Static Mechanical and Environmental Behaviours of Alkali-Activated-Strain-Hardening-Ultra-High-Performance Concrete

Abstract: The application of alkali-activated concrete (AAC) shows promise in reducing carbon emissions within the construction industry. However, the pursuit of enhanced performance of AAC has led to a notable increase in carbon emissions, with alkali activators identified as the primary contributors. In an effort to mitigate carbon emissions, this study introduces Na2CO3 as a supplementary activator, partially replacing sodium silicate. The objective is to develop a low-carbon alkali-activated-strain-hardening-ultra-h… Show more

“…In recent years, geopolymer has garnered widespread attention due to its notable characteristics, including high compressive strength, exceptional chemical resilience, and superior fire resistance [11][12][13]. Using silica-alumina-rich volcanic ash as a precursor material (such as metakaolin, FA, and GGBS), and employing alkaline activators (typically NaOH, Na 2 SiO 3 , or Na 2 CO 3 ), the material's reactivity is enhanced, initiating hydrolysis and polymerization reactions, thereby forming geopolymer materials [14]. Compared to traditional cement, geopolymer can reduce approximately 55% to 75% of carbon emissions and about 36% of energy consumption, making it a promising alternative to cement [15][16][17].…”

Comprehensive Analysis of Mechanical, Economic, and Environmental Characteristics of Hybrid PE/PP Fiber-Reinforced Engineered Geopolymer Composites

“…In recent years, geopolymer has garnered widespread attention due to its notable characteristics, including high compressive strength, exceptional chemical resilience, and superior fire resistance [11][12][13]. Using silica-alumina-rich volcanic ash as a precursor material (such as metakaolin, FA, and GGBS), and employing alkaline activators (typically NaOH, Na 2 SiO 3 , or Na 2 CO 3 ), the material's reactivity is enhanced, initiating hydrolysis and polymerization reactions, thereby forming geopolymer materials [14]. Compared to traditional cement, geopolymer can reduce approximately 55% to 75% of carbon emissions and about 36% of energy consumption, making it a promising alternative to cement [15][16][17].…”

Comprehensive Analysis of Mechanical, Economic, and Environmental Characteristics of Hybrid PE/PP Fiber-Reinforced Engineered Geopolymer Composites