Performance and characterization of nano-engineered silica waste concrete composite for efficient marine radionuclides remediation

Cement and Concrete Composites Pub Date : 2024-12-27 DOI:10.1016/j.cemconcomp.2024.105914

Jean-Baptiste Mawulé Dassekpo, Chonkei Iong, Dejing Chen, , Xiaoxiong Zha, Jianqiao Ye

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Abstract

The disposal of solid and radioactive waste poses significant risks to terrestrial and marine ecosystems. This study presents a sustainable solution by recycling silica-rich glass waste (RG) and fly ash (FA) to develop a functional nanocomposite concrete for radionuclide treatment. A Radionuclide removal Zeolite (RrZ) was hydrothermally synthesized from RG powder at low temperature and NaOH molar ratio. The RrZ was incorporated into a porous geopolymer composite concrete (PGCC) comprising 20% RrZ and 80% FA, with SiO₂/Na₂O = 1, liquid-to-solid ratio (L/S) = 0.33, paste-to-bone ratio (B/A) varying from 0.15–0.2, and porosity (P) from 14.95–25.45%. The results from SEM, TEM and BET indicated a highly porous structure of RrZ adsorbent with mesopores capable of achieving high adsorption efficiency (83.13–97.71% for Sr²⁺ and 55.31–91.01% for Cs⁺) within short time, adhering to the quasi-second-order kinetic models. Moreover, the XRD results identified key crystalline phase of analcime (NaAlSi₂O₆•H₂O), and no new phase formed after ion exchange with Sr²⁺ and Cs⁺, while the FTIR analysis revealed minimal chemical changes post-adsorption. Additionally, the porosity of 14.95% - 25.45% and water permeability of 1.876–11.956 mm/s were the key factors for PGCC design, while larger aggregates and lower B/A ratios helped to optimize the adsorption. The ANOVA analysis revealed that aggregate size was the most significant factor for single-cycle adsorption, followed by porosity and B/A ratio. This study demonstrates that PGCC effectively combines waste recycling with environmental remediation, offering a durable and efficient method for hazardous radionuclide removal from marine ecosystems.

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纳米工程二氧化硅废物混凝土复合材料对海洋放射性核素的高效修复性能及表征

固体和放射性废物的处置对陆地和海洋生态系统构成重大风险。本研究提出了一种可持续的解决方案，通过回收富硅玻璃废料（RG）和粉煤灰（FA）来开发用于放射性核素处理的功能纳米复合混凝土。以RG粉为原料，在低温和NaOH摩尔比下水热合成了放射性核素去除沸石（RrZ）。将RrZ掺入含有20% RrZ和80% FA的多孔地聚合物复合混凝土（PGCC）中，SiO₂/Na₂O = 1，液固比(L/S) = 0.33，膏骨比（B/ a）介于0.15-0.2之间，孔隙率(P)介于14.95-25.45%之间。SEM、TEM和BET结果表明，具有介孔的RrZ吸附剂具有高孔隙结构，能够在短时间内获得较高的吸附效率（Sr2 +为83.13-97.71%，Cs +为55.31-91.01%），符合准二级动力学模型。此外，XRD结果确定了铝酸盐的关键晶相（NaAlSi₂O₆•H₂O），与Sr2 +和Cs +离子交换后没有形成新的晶相，而FTIR分析显示吸附后化学变化很小。孔隙率为14.95% ~ 25.45%，渗透率为1.876 ~ 11.956 mm/s是PGCC设计的关键因素，较大的团聚体和较低的B/A比有助于优化吸附效果。方差分析表明，团聚体粒径是影响单循环吸附的最重要因素，其次是孔隙度和B/A比。该研究表明，PGCC有效地将废物回收与环境修复相结合，为海洋生态系统中有害放射性核素的清除提供了一种持久有效的方法。

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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Cement and Concrete Composites

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