光催化高级氧化与无机陶瓷膜分离技术耦合的研究

近年来,光催化高级氧化技术在深度水处理中已引起广泛关注。悬浮式光催化反应器作为一种高效光催化反应器,传质效果好、光利用率高,但光催化剂尤其是纳米光催化剂从悬浮液中的分离回收成为光催化高级氧化技术应用的难题。引入无机陶瓷膜分离技术来解决这一难题,设计了工艺流程,搭建了耦合装置并优化了工艺参数。该耦合系统在光催化高级氧化降解甲基橙(降解率达到99.1%以上)后能实现光催化剂的高效分离回收再利用,对光催化剂能达到99%以上的截留率。同时,研究更廉价、阻力降更小的膜材料及新型可见光响应光催化剂成为该技术发展的关键。

UV光催化高级氧化降解微囊藻毒素的研究进展

目前水体富营养化引起的水华问题越来越普遍,其中水华中蓝藻产生的微囊藻毒素带来的饮水安全问题越来越不容忽视,文章综述了UV/H2O2、UV/Ti O2、UV/O3高级氧化处理微囊藻毒素的研究进展并对未来进行了展望。

海运船舶尾气洗涤废水中多环芳烃对海洋污染的研究现状及展望

分析了海运船舶尾气洗涤废水排放对多环芳烃(PAHs)类污染物的海洋富集行为的影响以及对PAHs控制的制约因素和净化技术发展现状。PAHs的海洋富集趋势与船舶的发动机尾气排放行为呈正相关性,且船舶尾气洗涤废水排放加速了PAHs向海洋中富集。国际海事组织(IMO)尚未对在PAHs中占比大且毒性强的烷基化多环芳烃进行立法限制,但单方面采取措施禁止船舶尾气洗涤废水在其所属海域排放的国家和地区日益增多,洗涤废水排放的PAHs类污染物亟须净化处理。将高级氧化光催化技术应用于洗涤废水排放的PAHs净化具有发展前景。我国应抓住机遇,大力开展针对海洋PAHs的排放限制立法以及船舶尾气洗涤废水处理先进技术的研究,这对于提升我国海事管理水平、增大国际话语权,以及保护海洋生态安全具有重要意义。

Thermally-assisted photodegradation of lignin by TiO_2/H_2O_2 under visible/near-infrared light irradiation

As a bio-recalcitrant organic pollutant in paper mill effluent, lignin is generally removed by an advanced oxidation process, such as a TiO2/H2O2 photocatalytic technique under irradiation with ultraviolet light, which only accounts for less than 5% of sunlight. Herein, we reported a TiO2/H2O2-based thermally-assisted photocatalytic process that allows lignin to be efficiently degraded under visible/near-infrared light at an elevated temperature. Adsorption of H2O2 on TiO2 nanoparticles and an increase of temperature facilitate the production and separation of charge carriers under near-infrared and visible light irradiation, accelerate carrier transfer at the TiO2-electrolyte interface and promote the production of hydroxyl radicals, A higher level of H2O2 addition results in an increased degradation rate of lignin,while the optimal temperature for the thermally-assisted photodegradation of lignin is 70℃. A charge carrier excitation and transfer process was proposed for the TiO2/H2O2, thermally-assisted photocatalytic process. This work describes a new method for the photodegradation of organic pollutants,such as residual lignin in paper mill effluent, using wide band gap semiconductors under visible and near-infrared light irradiation.