Evaluation of rice husk biochar influence as a partial cement replacement material on the physical, mechanical, microstructural, and radiation shielding properties of ordinary concrete.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-07-26 DOI:10.1038/s41598-025-11987-8

Alaa A Mahmoud, Alaa A El-Sayed, Islam N Fathy, Samer Fawzy, Mansour Alturki, Maged E Elfakharany, Mohamed A Abouelnour, K A Mahmoud, Hany A Dahish, Soliman M ElTalawy, Islam M Nabil

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Abstract

This study investigated the viability of rice husk-derived biochar (RHB) as a partial substitute for cement in concrete. The used RHB, characterized by a novel chemical composition abundant in silicon and aluminum oxides, was incorporated into ordinary concrete at increasing substitution ratios up to 25% by cement weight. A comprehensive evaluation was conducted to assess the influence of RHB on various properties of concrete, including physical (setting time, standard consistency, workability), mechanical (compressive and tensile strength), microstructural (XRD, and EDX), and radiation shielding characteristics. The results indicated that RHB marginally increased cement setting time, with a maximum 7.14% increase observed at a 25% replacement level. However, it significantly increased water demand for standard consistency, reaching 35.7% at 25% replacement. The increased water demand correlated with a reduction in workability, with a maximum slump reduction rate of 57.3% at a 25% replacement level. The optimal replacement levels for mechanical strength enhancement were at 10% for compressive strength and 15% for tensile strength, achieving improvements of 13.74% and 9.48%, respectively. Additionally, Monte Carlo simulation code and PhyX software were employed for assessing gamma and fast neutron radiation attenuation characteristics of concrete. Gamma-ray attenuation tests revealed moderate improvements in the concrete's gamma-ray shielding capacity. Interestingly, the 15% RHB sample demonstrated a higher linear attenuation compared to the other samples, a result of its increased density. On the contrary, the 25RHB sample is less valuable. The 15RHB sample had the highest value for FCS (0.090 cm^-1) indicating its efficacy as a neutron shield.

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评价稻壳生物炭作为部分水泥替代材料对普通混凝土物理、机械、微观结构和辐射屏蔽性能的影响。

本研究探讨了稻壳衍生生物炭（RHB）作为混凝土中水泥的部分替代品的可行性。所使用的RHB具有丰富的硅和铝氧化物的新型化学成分，以增加取代比（水泥重量的25%）掺入普通混凝土中。综合评价RHB对混凝土各项性能的影响，包括物理性能（凝结时间、标准稠度、和易性）、力学性能（抗压强度和抗拉强度）、微观结构（XRD、EDX）和辐射屏蔽性能。结果表明，RHB略微延长了水泥凝结时间，在置换水平为25%时，最长可延长7.14%。然而，它显著增加了标准一致性的需水量，在置换25%时达到35.7%。需水量的增加与工作性的降低相关，在25%的替代水平下，坍落度的最大降低率为57.3%。机械强度提高的最佳替代水平为抗压强度10%和抗拉强度15%，分别提高13.74%和9.48%。此外，采用蒙特卡罗模拟代码和PhyX软件对混凝土的γ和快中子辐射衰减特性进行了评估。伽马射线衰减测试显示，混凝土的伽马射线屏蔽能力有适度改善。有趣的是，与其他样品相比，15%的RHB样品表现出更高的线性衰减，这是其密度增加的结果。相反，25RHB样品的价值较低。15RHB样品的FCS值最高（0.090 cm-1），表明其作为中子屏蔽的有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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