Mechanical Performance, Microstructure, and Porosity Evolution of Fly Ash Geopolymer after Ten Years of Curing Age

Aziz, Ikmal Hakem; Abdullah, Mohd Mustafa Al Bakri; Razak, Rafiza Abd; Yahya, Zarina; Salleh, Mohd Arif Anuar Mohd; Chaiprapa, Jitrin; Rojviriya, Catleya; Vizureanu, Petrică; Sandu, Andrei Victor; Tahir, Muhammad FaheemMohd; Abdullah, Abdul Rahman; Jamaludin, Shamsul Baharin

doi:10.3390/ma16031096

Cited by 4 publications

(3 citation statements)

References 22 publications

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“…As it is difficult to completely prevent cracking in concrete structures, monitoring the behavior of cracks is essential. However, conventional concrete with coarse aggregate has limited self-monitoring ability, as it lacks the added benefits of steel fibers and carbon black that can enhance the self-sensing ability of cracks [178][179][180]. Using steel fibers and carbon black in concrete can improve its self-monitoring ability by providing a more accurate way to detect and locate cracks.…”

Section: Effect Of Steel Fiber and Carbon Black On Concrete Cracksmentioning

confidence: 99%

“…The electrical resistance variance between two closely contacted electrodes was collected as a signal for strain measurement and compared with signals from lead zirconate titanate (PZT) sensors. The developed materials showed the potential for high-resolution strain measurement and stress wave detection without external instruments [178][179][180].…”

Section: Effect Of Steel Fiber and Carbon Black On Concrete Cracksmentioning

confidence: 99%

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Exploring the Potential of Promising Sensor Technologies for Concrete Structural Health Monitoring

Shilar,

Ganachari,

Patil

et al. 2024

Materials

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Structural health monitoring (SHM) is crucial for maintaining concrete infrastructure. The data collected by these sensors are processed and analyzed using various analysis tools under different loadings and exposure to external conditions. Sensor-based investigation on concrete has been carried out for technologies used for designing structural health monitoring sensors. A Sensor-Infused Structural Analysis such as interfacial bond-slip model, corroded steel bar, fiber-optic sensors, carbon black and polypropylene fiber, concrete cracks, concrete carbonation, strain transfer model, and vibrational-based monitor. The compressive strength (CS) and split tensile strength (STS) values of the analyzed material fall within a range from 26 to 36 MPa and from 2 to 3 MPa, respectively. The material being studied has a range of flexural strength (FS) and density values that fall between 4.5 and 7 MPa and between 2250 and 2550 kg/m3. The average squared difference between the predicted and actual compressive strength values was found to be 4.405. With cement ratios of 0.3, 0.4, and 0.5, the shear strength value ranged from 4.4 to 5.6 MPa. The maximum shear strength was observed for a water–cement ratio of 0.4, with 5.5 MPa, followed by a water–cement ratio of 0.3, with 5 MPa. Optimizing the water–cement ratio achieves robust concrete (at 0.50), while a lower ratio may hinder strength (at 0.30). PZT sensors and stress-wave measurements aid in the precise structural monitoring, enhanced by steel fibers and carbon black, for improved sensitivity and mechanical properties. These findings incorporate a wide range of applications, including crack detection; strain and deformation analysis; and monitoring of temperature, moisture, and corrosion. This review pioneers sensor technology for concrete monitoring (Goal 9), urban safety (Goal 11), climate resilience (Goal 13), coastal preservation (Goal 14), and habitat protection (Goal 15) of the United Nations’ Sustainable Development Goals.

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Section: Effect Of Steel Fiber and Carbon Black On Concrete Cracksmentioning

confidence: 99%

Section: Effect Of Steel Fiber and Carbon Black On Concrete Cracksmentioning

confidence: 99%

Exploring the Potential of Promising Sensor Technologies for Concrete Structural Health Monitoring

Shilar,

Ganachari,

Patil

et al. 2024

Materials

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“…In contrast to OPC concrete, geopolymer binders offer enhanced attributes such as superior resistance to both chemical and physical deterioration, rendering them particularly well-suited for deployment in challenging settings [7]. Furthermore, geopolymer binders have been found to engender notably diminished greenhouse gas emissions in comparison to OPC concrete, thus designating them as a more sustainable alternative for construction projects [13,14].…”

Section: Introductionmentioning

confidence: 99%

Effect of varying molarity and curing conditions on the mechanical and microstructural characteristics of alkali activated GGBS binder

2023

Mater. Res. Express

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Geopolymer binder offers a more sustainable choice for producing concrete in comparison to traditional ordinary Portland cement (OPC). The substitution of geopolymer binder for construction practices can decrease carbon dioxide emissions by decreasing OPC usage and repurposing industrial waste materials like ground granulated blast furnace slag (GGBS), fly ash, red mud, silica fume. In order to assess the suitability of GGBS as a binding material, it is essential to conduct conventional tests like consistency, setting times, and compressive strength, which are widely employed in cement testing. This study produced alkali activated paste (AAP) from GGBS and an alkaline activator comprising sodium hydroxide at various molarities from 1M to 8M. This investigation focused on the compressive strength of alkali-activated GGBS-based AAP under varying alkali activation molarities and curing conditions, including ambient, hot air oven, and humidity chamber curing. Additionally, the end reaction products of AAP showing higher compressive strength were examined for scanning electron microscopy (SEM), energy dispersive spectroscopy (EDS), X-ray diffraction (XRD) and Fourier transform infrared spectroscopy (FTIR) analysis. The experimental outcomes indicated that GGBS reduced the final setting time of AAP while increasing its compressive strength. Additionally, increasing the quantity of NaOH in the AAP increased its compressive strength. Furthermore, the research findings indicated that the mechanical properties of the alkali-activated GGBS-based material were notably influenced by the chosen curing conditions. Specifically, ambient curing demonstrated superior compressive strength, measuring at 47.06 MPa after 28 days, surpassing the results obtained from hot air oven curing and humidity curing.

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A comprehensive review on the strength, durability, and microstructural analysis of bacterial concrete

Shilar,

Ganachari,

Patil

2024

Structures

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Mechanical Performance, Microstructure, and Porosity Evolution of Fly Ash Geopolymer after Ten Years of Curing Age

Cited by 4 publications

References 22 publications

Exploring the Potential of Promising Sensor Technologies for Concrete Structural Health Monitoring

Exploring the Potential of Promising Sensor Technologies for Concrete Structural Health Monitoring

Effect of varying molarity and curing conditions on the mechanical and microstructural characteristics of alkali activated GGBS binder

A comprehensive review on the strength, durability, and microstructural analysis of bacterial concrete

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