Photocatalytic activity of TiO2 containing anatase nanoparticles and rutile nanoflower structure consisting of nanorods

A series of TiO2 with different crystal phases and morphologies was synthesized via a facile hydrothermal process using titanium nbutoxide and concentrated hydrochloric acid as raw materials. The photocatalytic activity of the samples was evaluated by degradation of Methyl Orange in aqueous solution under UV-Visible light irradiation. On the basis of detailed analysis of the characterizing results of high-resolution transmission electron microscopy, X-ray powder diffraction measurements, X-ray photoelectron spectroscopy and Brunauer-Emmett-Teller measurement, it was concluded that the photo-activity of the catalyst is related directly to the 3D morphology and the crystal phase composition. An excellent catalyst should have both a futile 3D flower-like structure and anatase granulous particles. The 3D flower-like structure could enhance light harvesting, as well as the transfer of reactant molecules from bulk solution to the reactive sites on TiO2. In addition, the optimum anatase/rutile phase ratio was found to be 80：20, which is beneficial to the effective separation of the photogenerated electron-hole pairs.     

Enhanced photocatalytic activity of quantum-dot-sensitized one-dimensionally-ordered ZnO nanorod photocatalyst

An efficient photocatalyst was fabricated by assembling quantum dots （QDs） onto one-dimensionally-ordered ZnO nanorods, and the photocatalytic properties for Methyl Orange degradation were investigated by scanning electron microscopy, transmission electron microscopy, X-ray diffraction, UV-Vis-NIR absorption spectroscopy and photoluminescence. The results indicate that the catalyst with assembled QDs is more favorable for the degradation than the pristine ZnO nanorods. The QDs with core-shell structure lower the photocatalytic ability due to the higher carder transport barrier of the ZnS shell layer. Besides its degradation efficiency, the photocatalyst has several advantages given that the one-dimensionally-ordered ZnO nanorods have been grown directly on indium tin oxide substrates. The article provides a new method to design an effective and easily recyclable photocatalyst.     

Critical velocity in phosphorus exchange processes across the sediment-water interface

Sediments are ultimate sinks of nutrients in lakes that record the pollution history evolutionary processes, and anthropogenic activities of a lake. However, sediments are considered as inner sources of environmental factor changes such as the variation in hydrodynamic conditions because of the nutrients they release. How does this process happen？ This study investigates a typical nutrient phosphorus （P） exchange among sediment, suspended particle matter （SPM）, and water. Compared with numerical and experimental studies, this study confirms that the critical velocity that occurs at a lower flow rate state exists in the range of 7 to 15 crn/sec. Critical velocity below the critical flow rate promotes the migration of particulate phosphorus （PP） to the SPM. On the other hand, critical velocity above the critical flow rate promotes the release of PP in water.     

磁性纳米Fe_3O_4对毒死蜱的增效和催化降解研究

应用溶剂热法制备了磁性纳米Fe3O4(NMFO),并用聚乙二醇-6000对其进行改性,使纳米Fe3O4表面由亲水性转变为亲脂性,从而实现与亲脂性毒死蜱的复合。纳米Fe3O4的加入使毒死蜱的生物活性明显提高。室内毒力试验结果表明:含0.2%纳米Fe3O4的Fe3O4/毒死蜱制剂的毒力在室内和紫外光照下分别是同浓度纯毒死蜱的3.84倍和4.17倍;其降解率也显著提高,纳米Fe3O4/毒死蜱制剂在太阳光照下放置10 d,其降解率可达93.2%,相同条件下纯毒死蜱的降解率是10.14%,而将添加或未添加纳米Fe3O4的毒死蜱于暗处放置相同的时间,其降解率分别为1.21%和0.23%。     

人造沸石负载纳米氧化镁同步脱氮除磷的研究

氮、磷是引发水体富营养化的限制性因素,控制水体中的氮、磷总量可以有效抑制水体富营养化的产生。以人造沸石为研究对象,探究不同改性方法对人造沸石同步去除水中氮、磷的影响。主要工艺为高温碱(NaOH)浸改善沸石结构,高温盐浸(MgCl)负载纳米态氧化镁。结果表明改性的最佳条件为:两阶段的烘干温度45℃;NaOH溶2+3-液浓度0.5 mol/L;MgCl溶液的浓度1 mol/L。对NH-N和PO的去除效率分别可达到83.76%和74.24%。对人造沸石2 4 4的热稳定性进行了实验,其烧失量达40.6%。最后,对吸附饱和的人造沸石进行脱附实验,脱附剂的选择为NaCl、KCl以及+3-两者的混合液。NaCl对NH4+-N和PO43-都有较为明显的脱附效果,脱附率分别可达84.54%和59.35%。     

活性炭固定耐冷菌对废水中硝基苯的降解

文章研究了颗粒活性炭固定鲍曼不动杆菌对硝基苯的降解情况。考查了活性炭对硝基苯的吸附等温线,符合Freulndlich经验公式,同时探究了其最佳投加量为5 mg/mL。较单纯微生物降解来说,在温度为15℃,pH为7,摇床转速140 r/min的条件下,生物活性炭降解浓度为200 mg/L的硝基苯所用时间大大缩短,而400 mg/L的硝基苯不能直接被菌株降解,固定化后84 h可基本完全降解,并且由于微生物作用活性炭得到再生。     

纳米氢氧化钛及焙烧产物对磷酸根的吸附特性研究

以纳米氢氧化钛(NTH)作为吸附水溶液中磷酸根的吸附剂,考察了NTH不同焙烧温度下的分子式及其对PO4吸附效果的影响。选择PO4初始浓度为50mg/L,通过正交试验确定在pH=2、吸附剂用量为0.1g、吸附时间3-3-为40min、温度25℃时,NTH吸附效果达到最佳,吸附量为55.5mg/g,经200、300、400及500℃焙烧后的NTH对磷酸根的吸附量逐渐减小;吸附量分别为49.4、40.6、25.5及16.8mg/g;NTH经800℃焙烧后,焙烧产物TiO2不具有吸附性。TG、XRD分析表明随着焙烧温度的升高,NTH的表面活性基团(-OH)数量逐渐减少。结果表明,吸附剂的吸附性与吸附剂表面羟基的数量有直接关系。     

浅析苯酚对硝化颗粒污泥活性的影响

好氧颗粒污泥是一种较为特殊的生物颗粒聚集体.它是由活性污泥微生物在外界选择压下通过自行固定方式形成较为紧凑的生理结构.好氧颗粒污泥在污水处理工艺中有着很多的应用,特别对在石油化工等行业应用较为广泛的苯酚的降解有着较好的处理效果.本论文研究了苯酚对于硝化颗粒污泥活性方面的影响,简述阐明了苯酚对硝化颗粒污泥可能产生的影响.     

高碳氮负荷下同时脱氮除碳好氧颗粒污泥研究

在4 L反应器中,以补加葡萄糖和硫酸铵的猪场废水为基质,不接种活性污泥,加入粉末状活性炭对废水土著微生物进行预固定.通过批次进水并控制运行条件（逐渐提高COD、NH 4＋-N负荷、缩短沉降时间、提高曝气量）培养同时脱氮除碳好氧颗粒污泥,研究了该好氧颗粒污泥的脱氮除碳功能及对高碳氮负荷冲击的响应.结果表明,成熟好氧颗粒污泥为土黄色不规则球状,粒径为0.5～3.5 mm.COD和NH 4＋-N负荷分别在4.80～12.6 kg.（m3.d）-1和0.217～0.503 kg.（m3.d）-1时,好氧颗粒污泥对COD的去除率〉94%,对NH 4＋-N的去除率〉98%.当COD和NH 4＋-N负荷分别提高至15.70 kg.（m3.d）-1和0.723kg.（m3.d）-1并运行4 d后,反应器内絮体激增,颗粒沉降变差并开始破碎,NH 4＋-N去除率下降至81.6%.排出部分污泥并降低负荷继续运行,颗粒污泥的NH 4＋-N去除率可迅速恢复至98%以上.本研究培养的好氧颗粒污泥具有良好的同时脱氮除碳功能,可以耐受高COD和NH 4＋-N负荷的双重冲击.     

pH和DO对好氧颗粒污泥去除高氨氮废水的影响研究

研究使用SBR成功培养的结构紧密、外形规则,具有良好脱氮性能的成熟好氧颗粒污泥处理高浓度氨氮废水,并探讨pH和DO对其处理效果的影响,旨在为工程实践提供理论依据。通过人工模拟废水,以蔗糖作为唯一碳源,NH4Cl为氮源,将进水NH4+-N浓度由300 mg/L逐步提高至900 mg/L,相应的NH4+-N负荷由0.6 kg/(m3.d)提高至1.8 kg/(m3.d),考察pH和DO对其处理效果的影响。研究结果表明:当控制反应器pH为8.0,曝气量为75 L/h时,好氧颗粒污泥脱氮的效果最好,氨氮去处率分别为96.70%9、2.33%。由于运行过程中每隔15 min监测每个反应器pH值,使其维持在各自pH值7.0±0.1范围内。这种酸碱度环境对异养菌等微生物并没有产生抑制作用;因此在各pH条件下,COD去除的所需时间和去除率基本没有差别。在不同的DO下,COD在初始的60 min里降解速度有明显区别。曝气量为150 L/h时,COD的降解速度最快,但是曝气量过大颗粒污泥内部厌氧区被压缩,因此选择最佳的曝气量为75 L/h。