AI Article Synopsis
- Cadmium (Cd) pollution poses a serious risk to human health, and innovative materials like biochar and nanomaterials show promise for addressing this issue due to their unique properties.
- A new composite material, SiONPs@BC (SBC), was created using silicon oxide nanoparticles and silkworm excrement biochar, which demonstrates a high specific surface area and effective adsorption capabilities for Cd in water and soil.
- Experimental results indicate that SBC significantly outperforms traditional materials in removing cadmium, improves soil quality, and transforms harmful cadmium into more stable forms, making it a viable solution for Cd remediation.
Article Abstract
Cadmium (Cd) pollution in water and soil seriously threatens human health. Biochar and nanomaterials have high potential for solving the cadmium pollution problem due to their abundant pores and high specific surface area. Here, the preparation of the composite material SiONPs@BC (SBC) using SiO NPs (SN) and silkworm excrement biochar (BC) is described, along with its application in the remediation of cadmium-contaminated water and soil. Characterization experiments (SEM&EDS, BET, FTIR, XRD, and XPS) demonstrated that SiONPs@BC has a high specific surface area (46.5767m/g), a well-developed pore structure (0.608375cm/g), and abundant surface functional groups (Si-C, Si-O, Si-O-Si), providing active sites for the adsorption of Cd. Batch adsorption experiments in water showed that the adsorption capacity of SBC is higher than that of biochar (BC) and SN, with a maximum Langmuir adsorption capacity of 141.99 mg/g. After five adsorption cycles, the removal rate of SBC was 73.04%, significantly higher than the 64.97% obtained for BC. The application of SBC not only improved the soil physicochemical properties by increasing the soil pH, the cation exchange capacity, and the soil organic matter content but also by reducing the amount of DTPA-Cd (24.6%) and the plant bioconcentration factor (28.28%) in the soil, converting Cd into more stable fractions (Red-Cd, Ox-Cd). Based on the results, SBC can effectively reduce Cd pollution.
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| http://dx.doi.org/10.1007/s10653-024-02243-5 | DOI Listing |
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