School of Resources, Environment and Materials, Guangxi University, Nanning 530004, PR China.
School of Resources, Environment and Materials, Guangxi University, Nanning 530004, PR China; College of Civil Engineering and Architecture, Guangxi University, Nanning 530004, PR China.
Sci Total Environ. 2021 Apr 10;764:144200. doi: 10.1016/j.scitotenv.2020.144200. Epub 2020 Dec 25.
In the traditional Fenton process, the efficient generation of hydroxyl radical (HO) strongly relies on an acidic circumstance and the iron ions would precipitate and form large amounts of hazardous iron-containing sludge at alkaline pH. To realize stable heterogeneous Fenton-like catalytic degradation at alkaline condition, FeO submicrospheres with SiO coating were successfully synthesized by using water glass as the silica sources via a facile ultrasound assisted method. The as-obtained FeO@SiO spheres were further used as catalysts for the Fenton-like degradation of tetracycline hydrochloride (TC). The FeO@SiO submicrospheres exhibited superior catalytic activity in higher pH environment (pH value = 11), and the degradation efficiency toward TC was ca. 80% after ten successive runs. The kinetics for the catalytic degradation of TC were agreed well with the second-order kinetic model. The reaction rate constant (k) over the FeO@SiO submicrospheres at a pH value of 11 was 7.69 times greater than that at a pH value of 3. Reactive species scavenging experiments revealed that HO and superoxide radical (O / HO) played a dominant role during the Fenton-like degradation of TC at pH 3 and pH 11, respectively. Possible Fenton-like degradation pathways of TC were proposed through the identification of intermediates using the high performance liquid chromatography coupled with mass spectrometry (HPLC-MS), which involved cleavage of methyl groups, N-dimethyl group, and hydroxy groups, ring-opening reaction, etc. The degradation efficiency of TC was close to 91.5% and total organic carbon (TOC) in solution was eliminated by about 41.4% at the optimized conditions. In a word, with the unique acidic surface properties and abundant Si-OH bonds, the FeO@SiO submicrospheres exhibited well dispersion, good catalytic activity, strong alkali resistance and excellent recyclability in an ultrasonic-Fenton-like system.
在传统的芬顿工艺中,羟基自由基 (HO) 的高效生成强烈依赖于酸性环境,而铁离子在碱性 pH 值下会沉淀并形成大量危险的含铁污泥。为了实现在碱性条件下稳定的非均相类芬顿催化降解,本文通过一种简单的超声辅助法,成功地利用水玻璃作为硅源合成了具有 SiO 涂层的 FeO 亚微米球。所获得的 FeO@SiO 球进一步用作盐酸四环素 (TC) 的类芬顿降解催化剂。在较高 pH 值环境 (pH 值=11) 下,FeO@SiO 亚微米球表现出优异的催化活性,经过十次连续运行后,TC 的降解效率约为 80%。TC 的催化降解动力学符合二级动力学模型。在 pH 值为 11 时,FeO@SiO 亚微米球的反应速率常数 (k) 比在 pH 值为 3 时大 7.69 倍。自由基捕获实验表明,在 pH 值为 3 和 11 时,HO 和超氧自由基 (O / HO) 分别在 TC 的类芬顿降解过程中起主导作用。通过高效液相色谱-质谱联用 (HPLC-MS) 鉴定中间产物,提出了 TC 的可能的类芬顿降解途径,包括甲基、N-二甲基和羟基的断裂、开环反应等。在优化条件下,TC 的降解效率接近 91.5%,溶液中总有机碳 (TOC) 去除率约为 41.4%。总之,FeO@SiO 亚微米球具有独特的酸性表面性质和丰富的 Si-OH 键,在超声类芬顿体系中表现出良好的分散性、优异的催化活性、较强的耐碱性和良好的可回收性。
