Manufacturing of high-performance light-weight mortar through addition of biochars of millet and maize

Seemab Tayyab, Anwar Khitab, Abdullah Iftikhar, Raja Bilal Nasar Khan, Mehmet Serkan Kirgiz
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引用次数: 3

Abstract

Agricultural wastes are environmental hazards, as these wastes can catch fire, resulting in the loss of human and animal lives and properties. Alternatively, the wastes are dumped in large spaces, which are already limited. Cementitious composites are quasi-brittle and develop cracks at the micro and nano level, which affect their strength, durability, and esthetics. Transforming agricultural wastes to biochar and using it as fibers in cementitious materials for crack arresting and enhancing fracture toughness is an environment-friendly approach. In this research, nano to microscale carbonaceous inert fibers (biochar) of millet and maize were prepared through pyrolysis followed by ball milling. The X-ray spectroscopy (EDX) revealed that 82.08% and 86.89% of the carbon content was retained in millet and maize, respectively. The scanning electron microscope (SEM) confirmed the presence of angular, flaky, and needle-like particles in the carbonaceous inerts, which may enhance the strength and the fracture response of the cementitious materials. These inerts were added individually to mortar specimens at dosage levels of 0, 0.025%, 0.05%, 0.08%, 0.2% and 1% by mass of cement. The dispersion of the synthesized nano inerts was ensured by UV–VIS spectroscopy. The compressive strength, flexural strength, porosity, and fracture toughness of cement mortar were evaluated. The carbonized nano intrusions reduced the porosity and density of the mortar specimens. The minimum porosity was noted with 1% and 0.08% dosages of millet and maize, respectively, whereas the minimum density was observed at 1% dosage for both. An increase in compressive and flexural strengths was also noticed. The compressive strength increased by 32% and 28% with 0.2% and 0.5% millet and maize, respectively. An increase of 168% and 114% in fracture toughness was noticed at optimized dosages of 0.5% and 1% of maize and millet, respectively. It is concluded that the addition of carbonaceous inert fibers of millet and maize resulted in light-weight porous mortars with enhanced strength and fracture toughness. The fracture toughness increases with dosage as the nanoparticles enhance the tortuosity.

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添加谷子和玉米生物炭制备高性能轻质砂浆
农业废物是环境危害,因为这些废物可能着火,造成人和动物生命和财产的损失。或者,废物被倾倒在已经有限的大空间里。胶凝复合材料是准脆性的,在微观和纳米水平上会产生裂缝,这会影响它们的强度、耐久性和美观性。将农业废弃物转化为生物炭,作为胶凝材料的纤维,用于止裂和提高断裂韧性是一种环保的方法。本研究以谷子和玉米为原料,通过热解-球磨法制备了纳米到微尺度的碳质惰性纤维(生物炭)。x射线光谱(EDX)分析表明,谷子和玉米的碳含量分别为82.08%和86.89%。扫描电镜(SEM)证实了碳质惰性中存在角状、片状和针状颗粒,这些颗粒可能增强了胶凝材料的强度和断裂响应。分别以水泥质量0、0.025%、0.05%、0.08%、0.2%和1%的剂量添加到砂浆试样中。用紫外可见光谱法对合成的纳米惰性物的分散性进行了验证。对水泥砂浆的抗压强度、抗折强度、孔隙率和断裂韧性进行了评价。碳化纳米侵入体降低了砂浆试样的孔隙率和密度。谷子和玉米在添加量为1%和0.08%时孔隙率最小,而密度在添加量为1%时最小。抗压和抗折强度的增加也被注意到。添加0.2%谷子和0.5%玉米,抗压强度分别提高32%和28%。玉米和谷子添加量分别为0.5%和1%时,其断裂韧性分别提高了168%和114%。综上所述,谷子和玉米碳质惰性纤维的加入使多孔砂浆重量轻,强度和断裂韧性均有所提高。随着纳米颗粒对弯曲度的增强,断裂韧性随添加量的增加而增加。
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