School of Environmental Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074, China.
School of Civil Engineering, Wuhan University, Wuhan 430072, China.
Environ Sci Technol. 2023 Jul 18;57(28):10478-10488. doi: 10.1021/acs.est.3c03370. Epub 2023 Jun 30.
Environmental-friendly and low-cost catalysts for peracetic acid (PAA) activation are vital to promote their application for micropollutant degradation in water. In this study, powdered activated carbon (PAC) was reported to improve the degradation of sulfamethoxazole (SMX). The improvement of SMX degradation in the PAC/PAA system was expected to be because of the PAA activation rather than the co-existing HO activation. Non-radical oxidation pathways, including the mediated electron-transfer process and singlet oxygen (O), were evidenced to play the dominant roles in the degradation of micro-organic pollutants. The graphitization of PAC, persistent free radicals, and electron-donating groups like C-OH were proposed to contribute to the activation of PAA. High SMX degradation could be achieved in the acidic and neutral conditions in the PAC/PAA system. Overall, higher dosages of PAC (0-0.02 g/L) and PAA (0-100 μM) benefited the degradation of SMX. The presence of HCO could lower the SMX degradation significantly, while Cl, PO, and humic acid (HA) only reduced the SMX degradation efficiency a little. Overall, this study offered an efficient non-radical PAA activation method using PAC, which can be effectively used to degrade micro-organic pollutants.
用于过氧乙酸 (PAA) 活化的环保且低成本的催化剂对于促进其在水中用于降解微量污染物的应用至关重要。在本研究中,报道了粉末状活性炭 (PAC) 可提高磺胺甲恶唑 (SMX) 的降解效率。PAC/PAA 体系中 SMX 降解效率的提高预计是由于过氧乙酸的活化,而不是共存的 HO 的活化。非自由基氧化途径,包括介导的电子转移过程和单线态氧 (O),被证明在微污染物的降解中起主要作用。PAC 的石墨化、持久自由基和 C-OH 等供电子基团被认为有助于 PAA 的活化。在 PAC/PAA 体系中,可在酸性和中性条件下实现高 SMX 降解。总的来说,PAC(0-0.02 g/L)和 PAA(0-100 μM)的较高剂量有利于 SMX 的降解。HCO 的存在会显著降低 SMX 的降解,而 Cl、PO 和腐殖酸 (HA) 仅稍微降低 SMX 的降解效率。总的来说,本研究提供了一种使用 PAC 进行有效非自由基 PAA 活化的方法,可有效用于降解微污染物。
