纳米二氧化钛光催化降解斯蒂酚酸影响因素的研究

研究了几种阳离子和pH值对纳米二氧化钛光催化降解斯蒂酚酸的影响。结果表明 :在实验条件下 ,Fe3+ 、Cu2 + 、Zn2 + 3种阳离子使光催化的效果增强 ,Mn2 + 对光催化产生一定的抑制作用 ,水体pH值高于或低于二氧化钛等电点时对光催化降解有促进作用。在实验研究的基础上 ,对机理进行了初步探讨     

苯酚水溶液光催化降解的盐效应

实验研究了不同浓度的NaCl, KCl, KBr, CaCl₂和Na₂SO₄等电解质对323K下苯酚水溶液光催化降解速度的影响,采用分光光度法测定了光催化降解的动力学曲线.结果表明,各种电解质对苯酚的光催化降解均有抑制作用,且随电解质浓度的增加而增强;盐效应强弱主要取决于阴离子而不是阳离子;对于所研究的体系,阴离子的盐效应作用顺序为Br->SO₄^2->Cl^-.光催化过程的盐效应可能与阴离子对光催化剂表面光生空穴的俘获和稳定作用以及阳离子的电导作用引起催化剂表面光生电子和空穴之间的短路有关.     

光催化体系中噻虫胺降解动力学及机制

利用光催化技术探讨了烟碱类杀虫剂噻虫胺在水体环境中降解的可行性,不同催化剂浓度、反应温度、底物浓度、溶液初始p H值和不同阴阳离子等因素对其光催化降解动力学的影响,及其初步的光催化降解机制.结果表明噻虫胺的光催化降解符合L-H动力模型,其降解假一级动力学速率常数为0.050 6 min-1.当催化剂用量(TiO_2)为3.0 g·L~(-1)时,噻虫胺的光催化降解速率最大;高温和较低的底物浓度有利于噻虫胺的光催化降解;溶液的初始p H值为5时噻虫胺的降解速率最大,强酸和强碱均不利于其光催化降解.而无机阴、阳离子对噻虫胺降解均有明显的抑制作用.最后,通过GC/MS对噻虫胺光催化降解中间产物进行了初步鉴定,研究发现在活性氧物种的作用下噻虫胺降解途径主要有母体化合物的羟基化,硝基胍基团中N—N的断裂,以及连接硝基胍和噻唑环的C—N键的裂解等.     

取代脲类除草剂光催化降解动力学比较

为研究取代脲类除草剂在TiO₂光催化降解过程中的动力学规律,以非草隆、异丙隆和利谷隆3种取代脲类除草剂为研究对象,通过Langmuir-Hinshelwood动力学模型对其TiO₂光催化降解动力学进行模拟,并系统探讨了催化剂用量、C₀(取代脲类除草剂的初始浓度)、溶液pH、温度、ROSs(活性氧物种)和电子捕获剂等的影响. 结果表明:非草隆、异丙隆和利谷隆的TiO₂光催化降解均符合假一级动力学模型,其动力学常数分别为0.082 8、0.068 7和0.095 4 min-1;取代脲类除草剂分子中的芳香环和脲桥上的取代基对降解速率常数的大小有明显的影响. ROSs试验表明,非草隆、异丙隆和利谷隆光催化降解过程中分别有91.6%、95.5%和86.8%的贡献来自·OH;而光生空穴和其他ROSs的贡献相对较小,并且电子捕获剂BrO₃-和S₂O₈2-对取代脲类除草剂的降解动力学有显著的促进作用.      

MnO2吸附-氧化去除草甘膦的研究

草甘膦是一种被广泛使用的除草剂,天然矿物的吸附-氧化作用对草甘膦的降解具有重要影响.本文研究了草甘膦在MnO2表面的吸附-氧化行为,考察了草甘膦在MnO2表面的降解动力学,以及反应体系pH和共存阳离子对MnO2吸附-氧化降解草甘膦的影响,初步分析了草甘膦的降解产物和可能的降解途径.结果表明,MnO2可有效降解草甘膦,草甘膦在MnO2表面的降解符合表观准一级动力学模型,表观反应动力学常数随草甘膦浓度的增大而减小;酸性条件有利于MnO2对草甘膦的去除,共存Cu2+对MnO2去除草甘膦有明显的抑制作用;草甘膦的降解产物包括肌氨酸、氨基乙酸、羟基乙酸、甲酸和乙酸及PO3-4、NH+4和NO-3.     

几种阴阳离子对磷钨酸光催化降解甲基橙的影响

以磷钨酸为光催化剂,在紫外灯照射下,对甲基橙溶液进行光催化降解,考察了几种阴阳离子对磷钨酸光催化降解甲基橙溶液的影响。结果表明：Mg^2＋、Ca^2＋、NO3^-、SO4^2-和CO3^2-均对催化活性有促进作用,其中Mg^2＋和Ca^2＋仅有微弱的促进作用;NO3^-和SO4^2-随着浓度的增加促进作用也有所增加;CO3^2-则随着浓度的增加促进作用呈下降趋势;Mn^2＋、Al^3＋和Cl^-对光解反应存在较强的抑制作用,且Al^3＋和Cl^-随着其浓度的增加,抑制作用增强。     

纳米TiO2薄膜光催化降解2,4-二氯酚的动力学研究

以主波长为365nm的紫外光灯为光源，纳米TiO2薄膜为光催化剂，研究了2，4-二氯酚光催化降解的产物及Cl^-对2，4-二氯酚光催化反应动力学的影响，并进一步探讨了Cl对2，4-二氯酚光解影响的机理，2，4-二氯酚可以经光催化氧化被彻底矿化，结合外加Cl^-对2，4-二氯酚光催化降解的影响和L-H反应动力学分析，可以认为Cl^-对2，4-二氯酚光催化降解的抑制作用，是由于Cl^-与2，4-二氯酚在TiO2表面竞争同一活性位点所致。因此，当光催化反应进行到Cl^-在TiO2表面竞争性吸附较强时，在反应动力学方程中必须考虑Cl^-的竞争性作用。     

无机离子对Fenton处理活性艳红X-3B染料废水的影响

针对实际染料废水中通常存在大量溶解性无机阴离子和金属阳离子的特点,选择了一些典型的无机离子,通过Fenton氧化降解偶氮染料活性艳红X-3B的试验,研究了无机离子对Fenton氧化降解的影响。结果表明,阴离子S2-对Fenton试剂催化氧化降解的抑制作用非常明显,H2PO4-和Cl-也具有不同程度的抑制作用,其抑制能力大小为:S2->H2PO4->Cl-;阳离子Cu2+和Mn2+抑制Fenton氧化作用的大小顺序为Cu2+>Mn2+;SO42-,NO3-,Mg2+和Zn2+对活性艳红X-3B的降解没有影响。研究结果可为Fenton方法处理含无机阴离子和金属阳离子的染料废水提供参考。     

天然斜发沸石对氨氮的快速吸附特性研究

通过静态摇床试验研究了天然斜发沸石对氨氮的吸附特性,以及沸石投加量和外加金属阳离子对其快速吸附氨氮特性的影响。结果表明,沸石对氨氮的等温吸附过程更符合Langmuir吸附模型,其最大吸附量为12.903mgg;沸石粒径减小,有利于沸石对氨氮的交换吸附,不同粒径沸石对氨氮的吸附均符合准二级动力学过程;斜发沸石中与氨氮进行离子交换的阳离子主要为Na+,其次为Ca2+,随着吸附氨氮浓度的升高或吸附时间的延长,Na+与NH4+吸附去除量的比值呈下降趋势,而Ca2+的比值呈上升趋势。沸石投加量与氨氮去除率和沸石释放至水中的总金属阳离子浓度成正比,随着投加量增加Na+与NH4+吸附去除量的比值由1.222增至1.383;溶液中分别加入40mgL的K+,Na+,Ca2+,Mg2+4种离子,对沸石吸附氨氮产生抑制作用的强弱顺序为K+Ca2+Na+Mg2+。     

TiO2薄膜降解印染废水的反应动力学研究

采用液相沉积法制备了石英砂负载纳米TiO2薄膜,对实际印染废水的光降解反应动力学进行了研究.结果表明:实际印染废水的光催化降解可用Langmuir-Hinshelwood 方程来描述,即浓度较高时,光催化降解符合零级动力学方程;浓度较低时,光催化降解在零级和一级反应之间.不同的pH值和H2O2投加量对反应的级数也有重要的影响,外加H2O2对光催化降解有极大的促进作用.     

Photocatalytic degradation of carbofuran in TiO2 aqueous solution：Kinetics using design of experiments and mechanism by HPLC/MS/MS

The photocatalytic degradation kinetics of carbofuran was optimized by central composite design based on response surface methodology for the first time. Three variables, TiO2 concentration, initial pH value and the concentration of carbofuran, were selected to determine the dependence of degradation efficiencies on independent variables. Response surface methodology modeling results indicated that the degradation efficiency of carbofuran was highly affected by the initial pH value and the concentration of carbofuran. Then nine degradation intermediates were detected by HPLC/MS/MS. The Frontier Electron Densities of carbofuran were calculated to predict the active sites on carbofuran attacked by hydroxyl radicals and photoholes. Point charges were used to elucidate the chemisorption pattern on TiO2 catalysts during the photocatalytic process. By combining the experimental results and calculation data, the photocatalytic degradation pathways of carbofuran were proposed, including the addition of hydroxyl radicals and the cleavage of the carbamate side chain.     

Parameters effect on heterogeneous photocatalysed degradation of phenol in aqueous dispersion of TiO_2

In this study, photocatalytic degradation of phenol selected as model compound of organic pollutant had been investigated in aqueous titanium dioxide (TiO2) dispersion under UV irradiation. The effects of various parameters such as pH, catalyst concentration, phenol concentration, anions, metal ions, electron acceptors, and surfactants on the photocatalytic degradation of phenol were investigated. The degradation kinetics was determined by the change in phenol concentration employing UV-Vis spectrometry as a function of irradiation time. The degradation kinetics of phenol follows pseudo first-order kinetics. The results showed a significant dependence of the photocatalytic degradation of phenol on the functional parameters. The probable promising roles of the additives on the degradation process were discussed.     

Effects of common inorganic anions on the rates of photocatalytic degradation of sodium dodecylbenzenesulfonate over illuminated titanium dioxide

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均相Co/PMS系统降解吡虫啉的影响因素及降解途径研究

过渡态Co^2+-催化分解KHSO₅(Co/PMS)系统是一种新型的高级氧化技术,其反应体系可以产生强氧化性的硫酸自由基(SO^·-₄).以杀虫剂吡虫啉为目标污染物,重点研究了溶液中PMS浓度、Co^2+-浓度和无机阴离子(H₂PO^-₄、HCO^-₃、NO^-₃和Cl^-)对Co/PMS系统降解吡虫啉的影响.结果表明,吡虫啉的降解遵循准一级动力学,其降解速率与氧化剂PMS浓度和催化剂Co^2+-的浓度呈正相关.吡虫啉的降解速率随着PMS和Co^2+-浓度的增加而增大,但是当PMS与吡虫啉的摩尔比大于20时,增加PMS的浓度对吡虫啉的降解速率反而有一定程度的抑制.H₂PO^-₄能促进Co/PMS系统对虫啉的降解;低浓度的HCO^-₃促进吡虫啉的降解,高浓度则为抑制作用;Cl^-抑制吡虫啉的降解,而NO^-₃则对整个降解过程影响不明显.研究中采用GC/MS分析吡虫啉降解的中间产物,得到了6-氯烟酸和6-氯烟酰胺2种主要的中间产物,并由此推测其可能的降解途径.     

pH值和离子对诺氟沙星在胡敏酸上吸附特征的影响

根据OECD Guideline 106批平衡实验,研究了pH值、Ca2+浓度和离子类型对诺氟沙星在胡敏酸上吸附特征的影响.结果表明,吸附系数(Kd)随着pH值的增大有先增加后减小的趋势,在pH 4.0和pH 6.0时吸附系数较大.红外光谱表明,pH 3.0有利于诺氟沙星和胡敏酸形成氢键; pH6.0和7.0时胡敏酸的羧基可能与诺氟沙星的氨基形成了肽键.诺氟沙星在胡敏酸上的吸附量和Kd值随着溶液中Ca2+离子浓度的增加而逐渐减小,表明两者之间存在阳离子吸附和竞争吸附.不同类型的阳离子和阴离子的加入都能导致诺氟沙星在胡敏酸的吸附特性存在差异.阳离子的影响趋势主要为价态的影响,即价态越高,在胡敏酸表面吸附位点的吸附能力就越强,对诺氟沙星吸附阻碍作用越显著,表现在诺氟沙星的最大吸附量(Qm)为:M+ (Na+、K+、NH4+) >M2+ (Mg2+、Ca2+、Zn2+);其次受阳离子的离子半径和水解作用的影响.而只有能水解的阴离子才能对诺氟沙星在胡敏酸上的吸附产生明显的阻碍作用.     

Parameters e ect on heterogeneous photocatalysed degradation of phenol in aqueous dispersion of TiO2

Photocatalytic degradation of phenol selected as model compound of organic pollutant had been investigated in aqueous titanium dioxide (TiO2) dispersion under UV irradiation. The e ects of various parameters such as pH, catalyst concentration, phenol concentration, anions, metal ions, electron acceptors, and surfactants on the photocatalytic degradation of phenol were investigated. The degradation kinetics was determined by the change in phenol concentration employing UV-Vis spectrometry as a function of irradiation time. The degradation kinetics of phenol follows pseudo first-order kinetics. The results showed a significant dependence of the photocatalytic degradation of phenol on the functional parameters. The probable promising roles of the additives on the degradation process were discussed     

Photocatalytic degradation of perfluorooctanoic acid with β-Ga2O3 in anoxic aqueous solution

Perfluorooctanoic acid (PFOA) is a new-found hazardous persistent organic pollutant, and it is resistant to decomposition by hydroxyl radical (HO·) due to its stable chemical structure and the high electronegativity of fluorine. Photocatalytic reduction of PFOA with β-Ga₂O₃ in anoxic aqueous solution was investigated for the first time, and the results showed that the photoinduced electron (e_cb^-) coming from the β-Ga₂O₃ conduction band was the major degradation substance for PFOA, and shorter-chain perfluorinated carboxylic acids (PFCAs, C_nF_2n+1COOH, 1 ≤ n ≤ 6) were the dominant products. Furthermore, the concentration of F^- was measured by the IC technique and defluorination efficiency was calculated. After 3 hr, the photocatalytic degradation efficiency was 98.8% and defluorination efficiency was 31.6% in the presence of thiosulfate and bubbling N₂. The degradation reaction followed first-order kinetics (k = 0.0239 min^-1, t_1/2 = 0.48 hr). PFCAs (C_nF_2n+1COOH, 1 ≤ n ≤ 7) were detected and measured by LC-MS and LC-MS/MS methods. It was deduced that the probable photocatalytic degradation mechanism involves e_cb^- attacking the carboxyl of C_nF_2n+1COOH, resulting in decarboxylation and the generation of C_nF_2n+1·. The produced C_nF_2n+1· reacted with H2O, forming C_nF_2n+1OH, then C_nF_2n+1OH underwent HF loss and hydrolysis to form C_nF_2n+1COOH.     

Photolysis of chlortetracycline in aqueous solution: Kinetics, toxicity and products

The aqueous photodegradation of the widely used antibiotic chlortetracycline (CTC) was investigated under simulated sunlight. The quantum yield of photodegradation increased from 3.3 × 10^-4 to 8.5 × 10^-3 within the pH range of 6.0 to 9.0. The presence of Ca²⁺, Fe³⁺, and NO₃^- enhanced the photodegradation of CTC, whereas Mg²⁺, Mn²⁺, and Zn²⁺ inhibited the degradation with the order Mn²⁺ > Zn²⁺ > Mg²⁺ at pH 7.3. The monovalent cations (Na⁺ and K⁺) had negligible effect on the photolysis of CTC. Fulvic acid (FA) decreased the photodegradation of CTC due to light screening effect. Hydrogen peroxide (H₂O₂) was formed concurrently with direct photodegradation of CTC. The generation rate of H₂O₂ increased from 0.027 to 0.086 μupmol/(L.min) when the pH ranged from 6.0 to 9.0. The CTC solution was about three-fold more toxic to the Photobacterium phosphoreum bacteria after irradiation, suggesting that the photoproducts and H₂O₂ formed in the CTC solution exhibited high risk on the bacteria. By LC-ESI(+)-MS, the photoproducts of CTC were identified. The direct photodegradation of CTC was involved in hydroxylation and N-demethyl/dedismethyl processes. The main photoproducts included the iso-CTC analog containing hydroxyl groups (m/z 511.4 and 495.4), and the N-demethyl/dedismethyl products of the photoproduct m/z 495.4 (m/z 481.3 and 467.4). In addition, the photochemical dechlorination of CTC led to tetracycline (m/z 445.5).