Effect of Coir Fiber Reinforcement on Properties of Metakaolin-Based Geopolymer Composite

Ayeni, Olugbenga; Mahamat, Assia Aboubakar; Bih, Numfor Linda; Stanislas, Tido Tiwa; Ibrahim, Isah; Savastano, Holmer; Boakye, Emmanuel E.; Onwualu, Azikiwe Peter

doi:10.3390/app12115478

Cited by 21 publications

(12 citation statements)

References 63 publications

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“…The toughness of the composite material increases, and the matrix and fiber also show a good bond without significant degradation. Hemicellulose and lignin cause the porosity of the composites, and their alkaline degradation reduces the degree of polymerization of the composites [ 27 , 28 ].…”

Section: Degradation Behavior Of Pfs In Geopolymer Matrixmentioning

confidence: 99%

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Alkaline Degradation of Plant Fiber Reinforcements in Geopolymer: A Review

Liu

2023

Molecules

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Plant fibers (PFs), such as hemp, Coir, and straw, are abundant in resources, low in price, light weight, biodegradable, have good adhesion to the matrix, and have a broad prospect as reinforcements. However, the degradation of PFs in the alkaline matrix is one of the main factors that affects the durability of these composites. PFs have good compatibility with cement and the geopolymer matrix. They can induce gel growth of cement-based materials and have a good toughening effect. The water absorption of the hollow structure of the PF can accelerate the degradation of the fiber on the one hand and serve as the inner curing fiber for the continuous hydration of the base material on the other. PF is easily deteriorated in the alkaline matrix, which has a negative effect on composites. The classification and properties of PFs, the bonding mechanism of the interface between PF reinforcements and the matrix, the water absorption of PF, and its compatibility with the matrix were summarized. The degradation of PFs in the alkaline matrix and solution, drying and wetting cycle conditions, and high-temperature conditions were reviewed. Finally, some paths to improve the alkaline degradation of PF reinforcement in the alkaline matrix were proposed.

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Section: Degradation Behavior Of Pfs In Geopolymer Matrixmentioning

confidence: 99%

“…In general, excess plant fibers adversely affect the compressive strength of the matrix. However, an appropriate amount of plant fibers can be evenly distributed in the matrix to enhance the compactness of the matrix, thus reducing porosity and cracks and improving compressive strength [ 28 , 29 ].…”

Section: Introductionmentioning

confidence: 99%

Alkaline Degradation of Plant Fiber Reinforcements in Geopolymer: A Review

Liu

2023

Molecules

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“…An appropriate amount of PFs content distributed evenly in the matrix can enhance the compactness of the composite, reduce the porosity and crack, and thus improve the compressive strength. Ayeni et al [ 91 ] studied geopolymer composites of 0.5, 1.0, 1.5, and 2.0% different weight of coir fibers contents. The compressive strength was increased from 16.91 N/mm 2 to 21.25 N/mm 2 by adding coir fibers with 0.5% fibers content.…”

Section: Mechanical Properties Of Pfrgsmentioning

confidence: 99%

“… Relationship between fibers content and compressive strength of composites [ 87 , 90 , 91 , 92 , 94 , 97 , 101 ]. …”

Section: Mechanical Properties Of Pfrgsmentioning

confidence: 99%

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The Mechanical Properties of Plant Fiber-Reinforced Geopolymers: A Review

Liu

Guo

et al. 2022

Polymers

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Both geopolymer and plant fiber (PF) meet the requirements of sustainable development. Geopolymers have the advantages of simple preparation process, conservation and environmental protection, high early strength, wide source of raw materials, and low cost. They have broad application prospects and are considered as the most potential cementitious materials to replace cement. However, due to the ceramic-like shape and brittleness of geopolymers, their flexural strength and tensile strength are poor, and they are sensitive to microcracks. In order to solve the brittleness problem of geopolymers, the toughness of composites can be improved by adding fibers. Adding fibers to geopolymers can limit the growth of cracks and enhance the ductility, toughness and tensile strength of geopolymers. PF is a good natural polymer material, with the advantages of low density, high aspect ratio. It is not only cheap, easy to obtain, abundant sources, but also can be repeatedly processed and biodegradable. PF has high strength and low hardness, which can improve the toughness of composites. Nowadays, the research and engineering application of plant fiber-reinforced geopolymers (PFRGs) are more and more extensive. In this paper, the recent studies on mechanical properties of PFRGs were reviewed. The characteristics of plant fibers and the composition, structure and properties of geopolymers were reviewed. The compatibility of geopolymer material and plant fiber and the degradation of fiber in the substrate were analyzed. From the perspective of the effect of plant fibers on the compression, tensile and bending properties of geopolymer, the reinforcing mechanism of plant fibers on geopolymer was analyzed. Meanwhile, the effect of PF pretreatment on the mechanical properties of the PFRGs was analyzed. Through the comprehensive analysis of PFFRGs, the limitations and recommendations of PFFRG are put forward.

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