评价骨炭/nTiO2复合材料与紫外辐射同时氧化吸附亚砷酸盐的能力

Sustainable Chemistry Pub Date : 2022-01-08 DOI:10.3390/suschem3010002

Susan Alkurdi, R. Al-Juboori, J. Bundschuh, A. Marchuk

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引用次数: 3

摘要

废水回用处理是推进循环经济、实现有效环境修复的重要途径。本研究考察了骨炭/二氧化钛纳米颗粒(BC/nTiO2)复合材料和紫外线对水中砷(III)和砷(V)的去除效果。该复合材料通过两种方式制备:在热解过程中和热解后向骨炭中添加nTiO2。与900°C (BC900)热解的未包覆骨炭相比，nTiO2沉积在骨炭上导致比表面积和孔体积分别从69减少到38 m2/g和0.23减少到0.16 cm3/g。而加入nTiO2后，孔径由14 nm略微增大到17 nm。热解制备的复合材料(BC/nTiO2)P对As的去除率优于超声热解后制备的复合材料(BC/nTiO2)US (57.3% vs. 24.8%)。复合材料(BC/nTiO2)P的砷酸盐氧化率比(BC/nTiO2)US高约3.5倍。在4 W、8 W和12 W的紫外功率下对亚砷酸盐的氧化和随后的吸附进行了测试，并与复合材料在可见光和单独的BC下进行了基准测试。结果表明，最高紫外功率处理效果最佳，吸附量为281µg/g，其次为BC单独处理，吸附量为196µg/g。这表明，由于nTiO2沉积造成的表面积和孔体积损失的影响只能通过施加高水平的紫外功率来补偿。

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Evaluating the Ability of Bone Char/nTiO2 Composite and UV Radiation for Simultaneous Oxidation and Adsorption of Arsenite

The reuse of waste materials for water treatment purposes is an important approach for promoting the circular economy and achieving effective environmental remediation. This study examined the use of bone char/titanium dioxide nanoparticles (BC/nTiO2) composite and UV for As(III) and As(V) removal from water. The composite was produced via two ways: addition of nTiO2 to bone char during and after pyrolysis. In comparison to the uncoated bone char pyrolyzed at 900 °C (BC900), nTiO2 deposition onto bone char led to a decrease in the specific surface area and pore volume from 69 to 38 m2/g and 0.23 to 0.16 cm3/g, respectively. However, the pore size slightly increased from 14 to 17 nm upon the addition of nTiO2. The composite prepared during pyrolysis (BC/nTiO2)P had better As removal than that prepared after pyrolysis with the aid of ultrasound (BC/nTiO2)US (57.3% vs. 24.8%). The composite (BC/nTiO2)P had higher arsenate oxidation than (BC/nTiO2)US by about 3.5 times. Arsenite oxidation and consequent adsorption with UV power of 4, 8 and 12 W was examined and benchmarked against the composite with visible light and BC alone. The highest UV power was found to be the most effective treatment with adsorption capacity of 281 µg/g followed by BC alone (196 µg/g). This suggests that the effect of surface area and pore volume loss due to nTiO2 deposition can only be compensated by applying a high level of UV power.

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Sustainable Chemistry

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