纳米0价铁催化双介质阻挡放电降解活性艳蓝X-BR的研究

为了证明纳米0价铁(nZVI)对于双介质阻挡放电降解染料废水的过程中具有较好的催化作用,本文以活性艳蓝X-BR为目标污染物,研究了在电压65V、电流0.92 A、反应时间为10 min时,nZVI对其在色度和TOC这2个方面的催化效果,并与Fe2+催化相比较。结果表明,nZVI的优化投加量为0.5g/L,在此投加量下活性艳蓝X-BR的去除率由88%提高到92%,TOC的去除率从16%提高到20%,并通过测定Fe2+和H2O2的含量变化来验证其作用机理。继而将nZVI和Fe2+的催化效果作比较,nZVI的催化效果要高于Fe2+,证明了nZVI耦合双介质阻挡放电对于活性艳蓝X-BR的去除有较好的的效果。

纳米零价铁对溶液中PCB77的降解及其影响因素

设计了以溶液初始pH值、3,3',4,4'-四氯联苯(PCB77)初始浓度、纳米零价铁(Fe0)投加量、纳米零价硅(Si0)投加量、腐殖酸和环糊精浓度为影响因素的正交试验,研究纳米Fe0降解PCB77时各因素对反应体系中PCB77残留率、氢离子浓度及氧化还原电位变化的影响及其相互关系。结果表明,在溶液初始pH值为4.5,初始ρ(PCB77)为1 mg.L-1,纳米Fe0投加量为10 g.L-1,纳米Si0投加量为0,ρ(腐殖酸)为0.25 g.L-1,ρ(环糊精)为1 g.L-1时,反应2 h后,PCB77残留率最低,为35.2%。溶液初始pH值对反应体系中PCB77的残留率影响最大,纳米Fe0投加量次之;溶液初始pH值对反应体系中氢离子浓度变化影响最大,环糊精投加量次之;PCB77初始浓度对反应体系中氧化还原电位变化影响最大,纳米Fe0投加量次之。

弱磁场强化氧化石墨烯负载纳米零价铁(GO-nFe^0/WMF)对水中Cr(Ⅵ)的去除特性及机制

利用共沉淀法成功制备出绿色、高效且具有较强重复利用性和抗氧化性能的介孔磁性材料氧化石墨烯负载纳米零价铁(GO-nFe0).通过场发射扫描电镜(FESEM)、透射电子显微镜(TEM)、傅立叶红外光谱仪(FTIR)、比表面积测试仪(BET)、X射线衍射仪(XRD)以及X射线光电子能谱分析(XPS)等表征手段对GO-nFe0的形貌、结构以及元素价态进行分析.研究了弱磁场(WMF)协同GO-nFe0体系(GO-nFe0/WMF)处理水体中Cr(Ⅵ)的特性和机制,并且考察了不同反应条件对体系去除Cr(Ⅵ)的影响.结果表明,当氧化石墨烯(GO)与纳米零价铁(nFe0)的负载质量比为1∶10且在20 mT弱磁感应强度的最佳条件下,GO-nFe0/WMF能够在30 min内完全去除浓度为10mg·L-1的Cr(Ⅵ).随着体系初始pH值的降低和材料投加量的增加,Cr(Ⅵ)的去除效率显著提高.无机阴离子(Cl-,SO42-)对Cr(Ⅵ)的去除表现出促进作用,而ClO-4和CO32-则分别表现出无明显影响和抑制效果.GO-nFe0在循环利用5次以及暴露空气中30 d仍能保持较高的反应活性.通过XRD、XPS以及邻菲啰啉掩蔽实验证明:GO-nFe0/WMF体系具有潜在的协同作用,GO可以提高WMF促进nFe0的腐蚀速率并提高电子转移速率,从而释放更多的Fe2+.

纳米颗粒0价铁氧化能力的判定

投加纳米颗粒0价铁（nZVI）DAO到含氧的水中，导致有机化合物的氧化。为了评估nZVI用于有机污染物氧化性转化的潜能，用苯甲酸（BA）向p-羟基苯甲酸（HBA）转变反应进行测试。当nZVI投加到含有BA的水中时，在首先的30min内检测p-HBA的波动，接下来，在至少24h以上的时间内，另外的D-HBA缓慢产生。

Synthesis of nanoscale zero-valent iron supported on exfoliated graphite for removal of nitrate

Nano ZVI particles supported on micro-scale exfoliated graphite were prepared by using KBH4 as reducing agent in the H2O/ethanol system. The supported ZVI materials generally have higher activity and greater flexibility for environmental remediation applications. The exfoliated graphite as the support was treated beforehand to hydrophilic material. Nano iron particles are deposited onto the rough graphite surface while those were formed by borohydride reduction. The possible nitrate reduction pathways were proposed. The TEM image shows that iron particles are highly dispersed on the surface of graphite and several of iron particles are imbedded in the pit of support surface. In this synthesis, iron particles have a nearly spherical shape with a grain size of 50?100 nm. The surface areas of materials with different iron loadings of 3.5%, 7.0%, 10.0%, 15.0% and 20.0%(mass fraction) are 2.89, 9.55, 8.45, 23.8 and 6.18 m2·g?1 by BET surface analyzer. The chemical reduction of nitrate by supported nano ZVI in aqueous solution were tested in series batch experiments. Experiment results suggest that NO3? can be more rapidly reduced to NH4+ at neutral pH and anaerobic conditions by supported nano ZVI than unsupported nano ZVI or ZVI scraps. The 15% nano Fe/graphite shows the best reduction efficiency contrasted with other Fe loading particles.