Rice straw ash: A potential pozzolanic supplementary material for cementing systems

Roselló, Josefa; Soriano, Lourdes; Santamarina, M. Pilar; Akasaki, Jorge Luís; Monzó, J.; Payá, J.

doi:10.1016/j.indcrop.2017.03.030

Cited by 79 publications

(30 citation statements)

References 33 publications

(33 reference statements)

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“…In this diagram, the ashes from different parts of Arundo donax are located in the K zone, which corresponds to low-acid biomass ashes rich in potassium and chlorine. These ashes derived from Arundo donax are very different from those found for rice husk, sugar cane leaf and bamboo leaf [11]. Table 2 summarizes the chemical compositions of the samples determined by EDX.…”

Section: Fesem Analysis Of Calcined Samples At 450 • Cmentioning

confidence: 82%

“…These include sugarcane bagasse ash (SCBA), studied in ordinary Portland cement (OPC) mixes [8,9], and sugarcane straw ash (SCSA), studied in geopolymeric systems based on blast furnace slag [10]. Rice straw ash (RSA) has been characterized and used to replace 10% and 25% OPC [11]. Wheat straw ash and corncob ash were studied by Memon et al [12,13] and demonstrated good pozzolanic performance of the ash, aiding in the production of environmentally friendly concrete.…”

Section: Introductionmentioning

confidence: 99%

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An Approach to a New Supplementary Cementing Material: Arundo donax Straw Ash

et al. 2018

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Arundo donax is a plant native to Asia and is considered an invader species in the Mediterranean region and many tropical zones in the world. These invader plants can be collected to produce a biomass, which can be converted to ash by combustion. The scope of the study is to assess the use of these ashes (Arundo donax straw ash [ADSA]) as supplementary cementing material due to their relatively high silica content. Electron microscopy studies on dried and calcined samples of different plant parts (cane, sheath leaf and leaf) were carried out. Some different cellular structures were identified in the spodogram (remaining skeleton after calcination). Major silica content was found in leaves and sheath leaves. The main element in all the ashes studied, together with oxygen, was potassium (22 to 46% depending on the part of the plant). Chloride content was also high (5–13%), which limits their use to non-steel reinforced concrete. The pozzolanic reactivity of ADSA was assessed in pastes by thermogravimetric analysis and in mortars with ordinary Portland cement based on compressive strength development. Excellent results were found in terms of reactivity.

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Section: Fesem Analysis Of Calcined Samples At 450 • Cmentioning

confidence: 82%

Section: Introductionmentioning

confidence: 99%

An Approach to a New Supplementary Cementing Material: Arundo donax Straw Ash

et al. 2018

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“…For example, some ashes derived from agricultural biomass, such as rice husk, biochar, and pam oil fuel ash, have been successfully used in cement or concrete as supplementary cementitious materials (SCMs). It is well-known that the use of rice husk ash in a concrete matrix can improve the strength and durability of concrete due to the pozzolanic reaction between highly reactive amorphous silica from rice husk ash and portlandite from cement hydration [8][9][10][11][12]. Cuthbertson et al [13] used biochar from residual biomass of the bio-ethanol industry as a concrete filler.…”

Section: Introductionmentioning

confidence: 99%

Can Common Reed Fiber Become an Effective Construction Material? Physical, Mechanical, and Thermal Properties of Mortar Mixture Containing Common Reed Fiber

et al. 2019

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Due to the increased demands of adapting the sustainability concept in the construction industry, many researchers have developed and evaluated the composite materials made with agricultural by-products, such as straws, fruit-shells, and cobs, as construction materials. Because no research work has been reported regarding the incorporation of common reed fiber (CRF) into a concrete composite to produce the green and sustainable concrete, this research has focused on the evaluation of physical, mechanical, and thermal properties of mortar mixture containing CRF regarding density, porosity, compressive and flexural strengths, and thermal conductivity. In total, six mixtures with 0%, 2%, 4%, and 6% CRF; 0.5% steel fiber (SF); and the combination of 6% CRF and 0.5% SF were prepared. Based on the experimental outputs, a simple analysis of heat loss was also been performed. The test results presented that the incorporation of CRF into mortar mixture proportionally reduced its unit weight and significantly increased its absorption capacity and porosity. Although the use of only CRF in the mortar mixture did not improve both compressive and flexural strengths compared to the plain mixture, the combined use of CRF and SF to increase both compressive and flexural strengths generated a synergetic effect to increase both strengths. The addition of CRF to the mixture has the benefit of producing a significant decrease in heat loss for a typical building in Astana due to the lower thermal conductivity and higher porosity to density ratio.

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“…The major components of RH are organic materials such as hemicellulose, cellulose, and lignin, totaling about 85%, and the remaining ash content is 15–20% [ 4 ]. Of all the residues of edible plants, the ash obtained from the calcined RH has the highest silica content [ 5 ].…”

Section: Introductionmentioning

confidence: 99%

Comparative Study of Water-Leaching and Acid-Leaching Pretreatment on the Thermal Stability and Reactivity of Biomass Silica for Viability as a Pozzolanic Additive in Cement

Wei

Chen

et al. 2018

Materials

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The present work aims to introduce a novel and eco-friendly method, i.e., a water-leaching pretreatment for extracting highly reactive biomass silica from rice husk (RH), for viability as a pozzolanic additive in cement. For comparison, the traditional acid pretreatment method was also employed throughout the experimental study. The silica from RH was extracted using boiled deionized water and acid solution as leaching agents to remove the alkali metal impurities, and then dried and submitted to pyrolysis treatment. The results indicated that potassium was found to be the major contaminant metal inducing the formation of undesirable black carbon particles and the decrease in crystallization temperature of amorphous RHA silica. The boiling-water-leaching pretreatment and acid-leaching pretreatment on RHs significantly removed the metallic impurities and reduced the crystallization sensitivity of RHA silica to calcination temperature. A highly reactive amorphous silica with purity of 96% was obtained from RH via 1 N hydrochloric acid leaching followed by controlled calcination at 600 °C for 2 h. The acid treatments increased the crystallization temperature of silica to 1200 °C and retained the amorphous state of silica for 2.5 h. In the case of water-leaching pretreatment, leaching duration for 2.5 h could yield an amorphous silica with purity of 94% and render the silica amorphous at 900 °C for 7 h. The RHA silica yielded by water-leaching pretreatment presented a comparable enhancing effect to that of acid leaching on hydration and improved the strength of cement. Furthermore, compared with the acid-leaching method, the water-leaching pretreatment method is more environmentally friendly and easier to operate, and hence more widely available.

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Rice straw ash: A potential pozzolanic supplementary material for cementing systems

Cited by 79 publications

References 33 publications

An Approach to a New Supplementary Cementing Material: Arundo donax Straw Ash

An Approach to a New Supplementary Cementing Material: Arundo donax Straw Ash

Can Common Reed Fiber Become an Effective Construction Material? Physical, Mechanical, and Thermal Properties of Mortar Mixture Containing Common Reed Fiber

Comparative Study of Water-Leaching and Acid-Leaching Pretreatment on the Thermal Stability and Reactivity of Biomass Silica for Viability as a Pozzolanic Additive in Cement

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