六氯苯的O3及UV/O3高级氧化降解试验研究

采用O₃、UV/O₃高级氧化法对水中六氯苯（HCB）的降解效果及机理进行了研究，并对结果进行了比较，结果表明，UV本身对HCB的去除率贡献不大，HCB可被O₃、UV/O₃快速降解，即UV＜O₃＜UV/O₃；O₃、UV/O₃作用时，提高体系的初始pH值不利于HCB的降解，在pH＝3，HCB=0.2 mg/L，反应40 min时，HCB的去除可达50%左右，酸性条件下有利于降解反应的进行；无论是O₃单独作用还是UV/O₃联合作用，HCB的降解基本上满足准一级反应动力学规律，如果体系的pH值基本保持恒定，这种规律就更为明显。根据离子色谱(IC)、GC对六氯苯降解中间产物进行了测定，探讨了O₃、UV/O₃降解六氯苯的途径和机理。     

铜基催化剂上甲苯深度氧化的机理分析

运用浸渍法制备了一系列CuO/γ-Al2O3催化剂,利用FTIR、MS、XRD等技术研究了甲苯在该催化剂上的深度氧化的性能及反应机理。初步讨论了活性氧化铝上铜的最佳负载量,铜在催化剂中的作用,以及甲苯在该催化剂上不同条件下反应的中间产物和最终产物及其产生机理。     

氨性条件下某些金属元素与氨配合反应的机理初探

在氨性条件下，银铜钯钴镍等均能与氨形成配合物，相应与所提供的配位体化合物的不同，直接影响反应的效果。选择合适的配合剂，以寻求最佳的反应结果。     

MnO_2基材料常温催化降解甲醛研究进展

甲醛(HCHO)是室内空气中的主要污染物之一,已被世界卫生组织确定为致癌和致畸形物质,对人体健康构成了极大威胁。常温催化技术在室温下即可将甲醛降解为无毒无害的CO_2和H2O,能耗低,具有较好的应用前景。二氧化锰(MnO_2)具有价格低廉、环境友好等优势,且晶型种类多,表现出优异的甲醛催化性能,具有较大的实际应用价值而被广泛研究。本文综述了MnO_2基催化剂,包括离子掺杂MnO_2、MnO_2固溶体和负载型MnO_2的甲醛催化活性及其制备方法,并探讨了其活性影响因素、常温催化反应机理,分析了其研究现状及发展趋势。     

Cl-/PMS体系降解甲氧苄啶的效能与机理

采用氯离子（Cl^－）作为阴离子活化剂,活化单过硫酸氢钾（PMS）氧化降解甲氧苄啶（TMP）.研究了Cl^－/PMS体系降解TMP中起主要作用的活性物种,同时考察了Cl^－浓度、PMS投加量、初始pH值对降解效果的影响,并研根据中间产物推断了TMP降解路径.实验结果表明,Cl^－/PMS体系中的主要活性物种是Cl^－和PMS直接反应生成的活性氯.降解过程符合拟一级反应动力学模型（R²>0.99）;随着Cl^－浓度和PMS投加量增加,反应速率常数k_obs增大;初始pH范围在5.0~9.0范围内,随着pH值的增大,TMP的去除率先减小后增大;TMP主要经历了氯取代和羟基取代过程,其核心结构上没有实质性的分解.     

Mechanism and kinetics study on the ozonolysis reaction of 2,3,7,8-TCDD in the atmosphere

The ozonolysis of 2,3,7,8-tetra-chlorodibenzo-p-dioxin(2,3,7,8-TCDD) is an efcient degradation way in the atmosphere. The ozonolysis process and possible reactions path of Criegee Intermediates with NO and H2 O are introduced in detail at the method of MPWB1K/6-31+G(d,p)//MPWB1K/6-311+G(3df,2p) level. In ozonolysis, H2O is an important source of OH radical formation and initiated the subsequent degradation reaction. The Rice-Ramsperger-Kassel-Marcus(RRKM) theory was applied to calculate rate constants with the temperature ranging from 200 to 600 K. The rate constant of reaction between 2,3,7,8-TCDD and O3 is 4.80 × 10 20cm3/(mole·sec) at 298 K and 760 Torr. The atmospheric lifetime of the reaction species was estimated according to rate constants, which is helpful for the atmospheric model study on the degradation and risk assessment of dioxin.     

Graphene-supported nanoscale zero-valent iron：Removal of phosphorus from aqueous solution and mechanistic study

Excess phosphorus from non-point pollution sources is one of the key factors causing eutrophication in many lakes in China,so finding a cost-effective method to remove phosphorus from non-point pollution sources is very important for the health of the aqueous environment. Graphene was selected to support nanoscale zero-valent iron(nZVI)for phosphorus removal from synthetic rainwater runoff in this article. Compared with nZVI supported on other porous materials,graphene-supported nZVI(G-nZVI) could remove phosphorus more efficiently. The amount of nZVI in G-nZVI was an important factor in the removal of phosphorus by G-nZVI,and G-nZVI with 20 wt.% nZVI(20% G-nZVI)could remove phosphorus most efficiently. The nZVI was very stable and could disperse very well on graphene,as characterized by transmission electron microscopy(TEM) and scanning electron microscopy(SEM). X-ray photoelectron spectroscopy(XPS),Fourier Transform infrared spectroscopy(FT-IR) and Raman spectroscopy were used to elucidate the reaction process,and the results indicated that Fe-O-P was formed after phosphorus was adsorbed by G-nZVI. The results obtained from X-ray diffraction(XRD) indicated that the reaction product between nZVI supported on graphene and phosphorus was Fe3(PO4)2·8H2O(Vivianite). It was confirmed that the specific reaction mechanism for the removal of phosphorus with nZVI or G-nZVI was mainly due to chemical reaction between nZVI and phosphorus.     

大气臭氧损耗中双自由基反应机理的量子化学研究

用量子化学ＲＨＦ理论方法研究了单重态双自由基ＮＨ,ＣＨ２、ＣＣＬ２与大气臭氧Ｏ３的反应机理。在３－２１Ｇ水平上用梯度解析技术优化了上述瓜在的反应物、中间体和产物构型,６－３１Ｇ或６－２１Ｇ计算能量,得到了各构型的有关结构数据。计算表明：上述反应分２步进行,双自由基先与Ｏ３反应生成稳定的中间体,然后在光照条件下中间体分解为ＮＨＯ、Ｈ２Ｃ烽ＣＬ２ＣＯ等稳定分子。从动力学看,２步反应分别为「π４ｓ＋Ｗ２     

电子自旋共振测定羟基自由基的研究

羟基自由基(·OH)是活跃性最强的氧分子,是一种重要的活性氧化剂,具有寿命短、浓度低等特点,是自然界中氧化能力仅次于氟的氧化剂,·OH能与有机物或无机物发生不同类型的反应,其氧化能力超过普通的化学氧化剂。文章介绍了·OH的氧化机理、性质及检测方法,并且分析了电子自旋共振法测定·OH的应用情况。     

硫酸盐还原厌氧氨氧化机理及其微生物研究进展

硫酸盐还原厌氧氨氧化（SRAO）是一种在厌氧条件下将氨氮氧化与硫酸盐还原耦合在一起的微生物过程,能够同时实现脱氮除硫且无需额外的电子受体,在废水处理领域备受关注。本文综述了SRAO的反应机理、SRAO功能微生物及其与其他微生物之间的相互作用,分析了目前SRAO研究中存在的不足,指出今后可以从生物信息学和分子生物学等角度,深入探讨SRAO体系中功能微生物之间的相互作用、揭示SRAO体系内N和S的循环途径、解析SRAO体系的内部机理,为SRAO工艺改进和工业应用提供理论支持。