School of Environment, Tsinghua University, Beijing, 100084, China.
China Tiegong Investment & Construction Group Co., Ltd, China.
Chemosphere. 2022 Dec;308(Pt 1):136089. doi: 10.1016/j.chemosphere.2022.136089. Epub 2022 Aug 23.
Microbially induced calcium carbonate precipitation (MICP) has been considered as a potential treatment method for the solidification and stabilization of municipal solid waste incineration fly ash (MSWI-FA).The main obstacle for MICP treatment of MSWI-FA is the harsh environment which causes the bacteria fail to maintain their urease activity effectively, thus decreases the solidification effect and material properties. Currently, there is no research on blending metakaolin (MK) as a protective carrier for the bacteria into the MSWI-FA. The effect of the MICP process on the curing properties of MSWI FA-based cementing materials in the MK and MSWI-FA reaction system is largely unknown. In this study, different mixing ratios of MK were used to adjust the Ca/Si/Al ratio in the mixture, and the properties of the cementing material (MSWI-FA mixed with MK and water) and the MICP-treated material (MSWI-FA mixed with MK and bacterial solution) were investigated. This study contributes to find suitable additives to promote effect of MICP on the solidification of MSWI-FA and the improvement of material properties. The results showed when the mixing ratio of MSWI FA was 90 wt %, the MICP treatment was able to increase the compressive strength of the samples up to 0.99 Mp, and the compressive strength of samples reached 1.46 MPa, when the mixing ratio of MSWI FA was 80 wt %. Though the metakaolin did not show inhibitory effect on the urease activity, the compressive strength of the MICP-treated samples did not further show a significant increase when the mixture of MK was increased from 20 wt% to 30 wt%. Further investigation suggested that MICP activities of bacteria utilizing calcium sources could have an impact on the formation/deformation of calcium-containing hydration products in the reaction system, thus affecting the mechanical and chemical properties of MSWI based materials. MICP treatment is effective in the immobilization of certain heavy metals of MSWI FA, especially for Pb, Cd and Zn. This research shows the potential of using MICP to treat the MSWI fly ash, meanwhile, it is necessary to find suitable reaction system with the proper additives in order to further improve the properties of the MSWI FA based material in terms of mechanical performance.
微生物诱导碳酸钙沉淀(MICP)已被认为是一种潜在的处理方法,用于固化和稳定城市固体废物焚烧飞灰(MSWI-FA)。MICP 处理 MSWI-FA 的主要障碍是恶劣的环境,这导致细菌无法有效地维持其脲酶活性,从而降低固化效果和材料性能。目前,还没有研究将偏高岭土(MK)作为细菌的保护载体混入 MSWI-FA 中。MICP 工艺对 MK 和 MSWI-FA 反应体系中 MSWI-FA 基胶凝材料固化性能的影响在很大程度上是未知的。在本研究中,使用不同比例的 MK 来调节混合物中的 Ca/Si/Al 比,并研究了胶凝材料(MSWI-FA 与 MK 和水混合)和 MICP 处理材料(MSWI-FA 与 MK 和细菌溶液混合)的性能。本研究有助于找到合适的添加剂来促进 MICP 对 MSWI-FA 固化和材料性能改善的作用。结果表明,当 MSWI-FA 的混合比例为 90wt%时,MICP 处理能够将样品的抗压强度提高到 0.99MPa,当 MSWI-FA 的混合比例为 80wt%时,样品的抗压强度达到 1.46MPa。虽然偏高岭土对脲酶活性没有抑制作用,但当 MK 混合物从 20wt%增加到 30wt%时,MICP 处理样品的抗压强度并没有进一步显著增加。进一步的研究表明,细菌利用钙源的 MICP 活性可能会影响反应体系中含钙水化产物的形成/变形,从而影响 MSWI 基材料的力学和化学性能。MICP 处理对 MSWI-FA 中某些重金属的固定化是有效的,特别是对 Pb、Cd 和 Zn。这项研究表明了利用 MICP 处理 MSWI 飞灰的潜力,同时,有必要找到合适的反应体系和适当的添加剂,以进一步提高 MSWI-FA 基材料在力学性能方面的性能。
