柠檬酸-Fe(Ⅱ)/K2S2O8对敌草隆降解的研究

研究了初始pH值为3.0时敌草隆在柠檬酸-Fe(Ⅱ)/K2S2O8体系中的降解行为.结果显示,0.1mmol·l-1敌草隆的最佳降解条件为:[K2S2O8]=2.0mmol·l-1,[Fe(Ⅱ)]=1.0mmol·l-1,[CA]=0.5mmol·l-1.在该条件下,敌草隆的降解符合一级反应动力学,半衰期为30.5min.此外,采用分子探针法鉴定了体系中产生的硫酸根自由基和羟基自由基.并采用液-质联用技术鉴定了敌草隆在柠檬酸-Fe(Ⅱ)/K2S2O8体系中的降解产物,探讨敌草隆在柠檬酸-Fe(Ⅱ)/K2S2O8体系中可能的降解机理.     

UV/Fe3+/H2O2体系降解活性艳橙X-GN废水的研究

采用UV/Fe3 /H2O2体系光解活性艳橙X-GN模拟废水,考察了X-GN,Fe3 和H2O2的初始浓度、初始pH值及温度对光解的影响,探讨了X-GN的降解途径和机理.结果表明,在8W低压汞灯(λ＝254nm)照射下,UV/Fe3 /H2O2能够有效地降解X-GN,在pH=3.0,T=50 ℃,时间为120 min,Fe3 和H2O2的初始浓度分别为2.5×10-5 mol·l-1和1.5×10-4 mol·l-1时,对含200 mg·l-1 X-GN模拟废水的色度去除率和矿化率分别达到100%和90.15%.用IC和GC/MS对X-GN降解的中间产物和最终产物进行分析,推导出UV/Fe3 /H2O2体系中X-GN降解的途径和机理.     

分子筛负载Fe3+可见光协助降解有机污染物

通过NaY型分子筛负载Fe3 制备异相Fenton催化剂(FeY),采用FeY在可见光(λ＞420 nm)照射下研究其降解染料罗丹明B(RhB)和2,4-二氯苯酚(DCP).通过对RhB降解过程的紫外-可见光谱、ESR和红外光谱分析,以及总有机碳量(TOC)的跟踪测定,FeY/H2O2体系在可见光照射下能有效地降解RhB,降解反应主要涉及到·OH自由基的产生和参与.RhB/FeY/H2O2体系在可见光照射下,反应270min,RhB脱色率达到100%,TOC去除率达75.6%.DCP/FeY/H2O2体系在可见光照射下,反应150min,DCP降解率达81.0%.利用酶催化反应米氏方程测定催化剂的活性,FeY催化常数Kcat=2.28×105 mol·l-1·min-1.     

Fenton试剂氧化降解微囊藻毒素-LR

研究了Fenton试剂氧化降解微污染水体中微囊藻毒素MC-LR的效果,在H2O2浓度1.5mmol·l-1,Fe2 浓度0.10 mmol·l-1,反应温度为25±1℃,pH值为4.18及反应时间为30min的条件下,浓度为0.41mg·l-1的MC-LR去除率可以达到92.4%,降解过程符合准一级反应动力学.Fenton试剂氧化体系能有效地降解MC-LR,特别是在紫外光的照射下,MC-LR的降解速率得到大幅度提高.紫外光能促进Fe3 还原为Fe2 ,所以光助Fenton试剂氧化反应中可以使用Fe3 代替Fe2 .     

铁锰矿类Fenton异相光催化降解有毒有机染料

选取6种天然铁锰矿石为光催化剂,以可见光(λ420nm)照射下活化H2O2降解有机染料罗丹明B(RhodamineB,RhB)为探针反应,筛选出活性较高的天然矿石(磁赤铁矿)催化降解RhB及2,4-二氯苯酚(2,4-Dichlorophenol,DCP).实验表明,可见光下磁赤铁矿在pH=7.0的介质体系,H2O2浓度为3×10-3mol·l-1条件下可有效降解RhB.通过反射紫外光谱、原子吸收分光光度法、XRD初步表征了磁赤铁矿组成结构;采用紫外-可见吸收光谱(UV-vis)、红外光谱(IR)、总有机碳(TOC)测定等方法,研究了其可见光照射下对RhB光催化降解特性.结果表明,在实验条件下RhB矿化率达60%,DCP矿化率达到63.93%.利用电子自旋捕捉技术(ESR)跟踪测定RhB降解过程中氧化物种,表明催化降解过程涉及羟基自由基(·OH)氧化过程.拟定异相矿石类Fenton体系与传统均相Fenton体系相比,具有反应介质pH范围宽(3.0—7.0)、可见光激发及催化剂易得廉价等优势。     

Fe_3O_4@Graphite电极中性条件下电Fenton降解有机污染物

制备了Fe3O4复合石墨电极(Fe3O4@graphite),通过循环伏安测定,对自制电极的电化学特性进行了表征.在外加电压无隔膜反应池中,基于Fe3O4@graphite为阴极,铂网为阳极,在pH7.0中性条件下,探讨了降解有机染料罗丹明B(Rhodamine B,RhB)及无色小分子2,4-二氯苯酚(2,4-dichlorophenol,DCP)的电Fenton反应特性,结果表明,对1.0×10-5mol.l-1RhB在外加电压6 V和支持电解质Na2SO410 g.l-1条件下,电Fenton反应120 min,RhB降解率达100%.采用过氧化物酶催化反应吸光光度法和苯甲酸荧光分析法跟踪测定RhB降解反应过程中H2O2和羟基自由基(.OH)的变化,表明RhB降解过程涉及.OH历程.采用红外光谱分析和TOC测定RhB降解过程中深度氧化变化,表明电Fenton反应条件下,RhB反应过程中其分子结构被破坏,生成羧酸或者胺类小分子化合物,同时180 min矿化率达59.2%,对2,4-DCP而言,240 min降解率为98.6%,14h矿化率为86.8%.     

Fe0体系降解2,4-二氯酚的影响因素及其反应机理

采用铁屑、炉渣及河砂混合介质降解2,4-二氯酚(2,4 - DCP)模拟废水,研究铁屑粒径、铁屑投加量、铁屑与炉渣配比、pH值等因素对2,4- DCP脱氯效果的影响,探讨Feo体系降解2,4- DCP的反应机理.结果表明,铁屑粒径、铁屑投加量、铁屑与炉渣配比、pH对2,4- DCP脱氯效果均有显著影响,在铁屑粒径为2～5mm、不改变废水pH、铁屑与炉渣质量比为31:9条件下,Feo体系对2,4- DCP去除率高达97％.2,4- DCP经脱氯后主要产物为2-氯酚、4-氯酚和苯酚,反应后废水的可生化性明显提高,利于后续的生物处理.     

Fe-C-H_2O_2协同催化氧化处理印染废水

用Fe-C-H2O2协同催化氧化体系对印染工业废水的降解脱色处理进行了研究。对影响印染废水降解的几种因素如铁屑/碳粒质量比、双氧水的质量分数、废水pH等进行考察。试验结果表明,对于色度为650度和ρ（COD）为468mg·L-1的印染废水,在废水pH=4.8的情况下,当铁屑/碳粒质量比为25∶1、H2O2用量为150mg·L-1、催化反应30min时,印染废水的脱色率达98%以上,CODCr去除率可达78%。与Fe-C微电解法相比,Fe-C-H2O2协同催化氧化方法对印染废水的脱色能力和去除COD,表现出了更好的处理效果。     

电-Fenton法降解青霉素的动力学研究

采用电-Fenton法处理青霉素钠(Penicillin G sodium, PGN)模拟废水,当T=20℃,pH=3时,投加0.5g·l-1 FeSO4和0.2ml·l-1 H2O2,在0.6A电流下降解青霉素钠废水(100 mg·l-1), 20min后青霉素钠去除率为79%,40min后去除率为95%.拟合实验数据得到青霉素钠降解反应的速率方程式为:-d[PGN]/dt=2.35×106 exp(-32869.4/RT )[Fe2 ]0.53[H2O2]0.8[PGN]1.14反应速率常数和反应级数表明,初始阶段降解反应进行非常迅速,且H2O2浓度比Fe2 浓度对电-Fenton降解反应的影响重要.     

改性TiO2光催化膜的制备及其光催化降解2,4-DCP的研究

利用活性炭粉末对TiO2光催化剂进行改性,并对2,4-二氯苯酚进行光催化降解.结果表明,改性后TiO2光催化剂的光催化活性较之改性前有很大的提高.在pH=10,活性炭粉末掺杂量为10mg·ml-1时,300W高压汞灯下光催化降解120min,2,4DCP的去除率可达96.75%.     

SO2-4/TiO2对SO2-C7H16-TiO2复相光化学反应的影响

研究了TiO2与SO2,C7H16复相光化学反应的光催化活性.在SO2-C7H16-O2-TiO2光催化反应过程中,TiO2表面可形成SO2-4/TiO2结构,它的存在可提高庚烷的光催化氧化速率,利用IR和XPS研究了反应过程中TiO2表面形成的SO2-4/TiO2结构.     

Cu/Cr co-stabilization mechanisms in a simulated Al2O3-Fe2O3-Cr2O3-CuO waste system

• Cu and Cr can be mostly incorporated into CuFe_xAl_yCr_2−x−yO₄ with a spinel structure. • Spinel phase is the most crucial structure for Cu and Cr co-stabilization. • Compared to Al, Fe and Cr are easier to be incorporated into the spinel structure. • ‘Waste-to-resource’ by thermal process at attainable temperatures can be achieved. Chromium slag usually contains various heavy metals, making its safe treatment difficult. Glass-ceramic sintering has been applied to resolve this issue and emerged as an effective method for metal immobilization by incorporating heavy metals into stable crystal structures. Currently, there is limited knowledge about the reaction pathways adopted by multiple heavy metals and the co-stabilization functions of the crystal structure. To study the Cu/Cr co-stabilization mechanisms during thermal treatment, a simulated system was prepared using a mixture with a molar ratio of Al₂O₃:Fe₂O₃:Cr₂O₃:CuO= 1:1:1:3. The samples were sintered at temperatures 600–1300°C followed by intensive analysis of phase constitutions and microstructure development. A spinel phase (CuFe_xAl_yCr_2−x−yO₄) started to generate at 700°C and the incorporation of Cu/Cr into the spinel largely complete at 900°C, although the spinel peak intensity continued increasing slightly at temperatures above 900°C. Fe₂O₃/Cr₂O₃ was more easily incorporated into the spinel at lower temperatures, while more Al₂O₃ was gradually incorporated into the spinel at higher temperatures. Additionally, sintered sample microstructures became more condensed and smoother with increased sintering temperature. Cu / Cr leachability substantially decreased after Cu/Cr incorporation into the spinel phase at elevated temperatures. At 600°C, the leached ratios for Cu and Cr were 6.28% and 0.65%, respectively. When sintering temperature was increased to 1300°C, the leached ratios for all metal components in the system were below 0.2%. This study proposes a sustainable method for managing Cu/Cr co-exist slag at reasonable temperatures.     

Catalytic ozonation of organic compounds in water over the catalyst of RuO2/ZrO2-CeO2

This research investigates the performances of RuO₂/ZrO₂-CeO₂ in catalytic ozonation for water treatment. The results show that RuO₂/ZrO₂-CeO₂ was active for the catalytic ozonation of oxalic acid and possessed higher stability than RuO₂/Al₂O₃ and Ru/AC. In the catalytic ozonation of dimethyl phthalate (DMP), RuO₂/ZrO₂-CeO₂ did not enhance the DMP degradation rate but significantly improved the total organic carbon (TOC) removal rate. The TOC removal in catalytic ozonation was 56% more than that in noncatalytic ozonation. However this does not mean the catalyst was very active because the contribution of catalysis to the overall TOC removal was only 30%. The adsorption of the intermediates on RuO₂/ZrO₂-CeO₂ played an important role on the overall TOC removal while the adsorption of DMP on it was negligible. This adsorption difference was due to their different ozonation rates. In the catalytic ozonation of disinfection byproduct precursors with RuO₂/ZrO₂-CeO₂, the reductions of the haloacetic acid and trihalomethane formation potentials (HAAFPs and THMFPs) for the natural water samples were 38%–57% and 50%–64%, respectively. The catalyst significantly promoted the reduction of HAAFPs but insignificantly improved the reduction of THMFPs as ozone reacts fast with the THMs precursors. These results illustrate the good promise of RuO₂/ZrO₂-CeO₂ in catalytic ozonation for water treatment.     

Immobilization of Cu2+, Zn2+, Pb2+, and Cd2+ during geopolymerization

The present research explored the application of geopolymerization for the immobilization and solidification of heavy metal added into metakaolinte. The compressive strength of geopolymers was controlled by the dosage of heavy metal cations, and geopolymers have a toleration limit for heavy metals. The influence of alkaline activator dosage and type on the heavy metal ion immobilization efficiency of metakaolinte-based geopolymer was investigated. A geopolymer with the highest heavy metal immobilization efficiency was identified to occur at an intermediate Na₂SiO₃ dosage and the metal immobilization efficiency showed an orderly increase with the increasing Na⁺ dosage. Geopolymers with and without heavy metals were analyzed by the X-ray powder diffraction (XRD) and Fourier transform infrared (FTIR) spectroscopy. No crystalline phase containing heavy metals was detected in geopolymers with heavy metal, suggesting that the crystalline phase containing heavy metals is not produced or most of the phases incorporating heavy metals are amorphous. FTIR spectroscopy showed that, with increasing heavy metal addition, an increase in NO3- peak intensity was observed, which was accompanied by a decrease in the CO32- peak.