纳米Ag2O2-PbO2化学修饰电极对大肠杆菌细胞膜壁和DNA损伤的研究

制备了一种新型纳米AgO2-PbO2修饰电极,在选定的正电位下,电极表面产生羟基自由基(.OH).通过测定产生的脂质过氧化物和漏出蛋白质的量来研究羟基自由基对大肠杆菌细胞膜壁损伤的情况,并运用电泳和DNA测序的方法对大肠杆菌质粒DNA的损伤及其对序列变化进行了研究.     

银掺杂介孔氧化铝抗菌剂的一步合成与表征

以Al(NO_3)_3·9H_2O和AgNO_3为原料,采用水热法制备了介孔氧化铝纳米粒子(Mesoporous Al_2O_3NPs)和银掺杂介孔氧化铝纳米粒子(Mesoporous Ag/Al_2O_3NPs),通过X射线衍射(XRD)、场发射扫描电子显微镜(FE-SEM)、X射线荧光光谱(XRF)、能量分散X射线衍射(EDX)和低温N2吸附-脱附等手段对产物进行了表征,通过最低抑菌浓度和抑菌圈实验研究了材料的抗菌性能.XRD分析表明在介孔Ag/Al_2O_3NPs中Al_2O_3是唯一结晶相,Ag掺杂后,介孔Ag/Al_2O_3NPs晶格常数和半高峰宽增大,晶面间距[(111),(400)和(440)面]减小.FE-SEM形貌分析表明掺杂后的介孔Ag/Al_2O_3NPs颗粒直径减小而孔径增大.EDX和XRF分析表明介孔Ag/Al_2O_3NPs中O/Al摩尔比为1.5,与Al_2O_3NPs中O/Al摩尔比相同.综合XRD和XRF分析结果认为,Ag进入介孔Al_2O_3晶格间隙形成间隙固溶体.低温N2吸附-脱附分析表明掺杂后的介孔Ag/Al_2O_3NPs比表面积、孔体积和孔径增大.曝气抗菌实验结果表明介孔Ag/Al_2O_3NPs的抗菌机理是活性氧和金属银的协同作用.介孔Ag/Al_2O_3NPs对革兰氏阴性菌(大肠杆菌)和革兰氏阳性菌(金黄色葡萄球菌)具有明显的抗菌效果,对大肠杆菌和金黄色葡萄球菌的最低抑菌浓度(MIC)均为80μg/m L,抑菌圈直径分别为26 mm和24 mm.     

纳米B2O3/TiO2复合材料的制备及其对痕量银的分离富集性能研究与应用

制备了新型纳米B2O3/TiO2吸附材料,并采用扫描电镜(SEM)及红外光谱(IR)对其进行表征,优化了纳米B2O3/TiO2复合材料对试液中痕量银的吸附和解吸条件,建立了纳米B2O3/TiO2分离富集-原子吸收光谱测定痕量银的新方法。当pH 4.3时,在22℃下振荡20 min,Ag+能被该材料快速吸附,其静态饱和吸附容量为11.72 mg/g,吸附在纳米B2O3/TiO2上的Ag+可用0.1 mol/L HNO3-0.05 mol/L硫脲(1∶4)完全洗脱。该方法的检出限为2.01μg/L,线性范围为0.01～4.00 mg/L,相对标准偏差(RSD)为1.8%,加标回收率为95%～105%。方法应用于实际矿渣样品中痕量银的测定,结果满意。     

Bactericidal mechanism of Ag/Al2O3 against Escherichia coli

The bactericidal process of Ag/Al2O3 to Escherichia coli has been investigated to clarify the bactericidal mechanism. In SEM images, the configuration of E. coli cells contacting with the catalyst surface was quite different from that contacting with AgNO3 solution, which indicated that the Ag+ eluted from the catalyst did not play an important role in the bactericidal process. The bactericidal experiments strongly confirmed the contribution of multiform reactive oxygen species (ROS) (super oxide dismutase (SOD) and catalase as the scavengers for O2*- and H2O2, respectively) to bactericidal effect on the catalyst surface. Furthermore, the surface modification of Ag/Al2O3 by ultraviolet and formaldehyde influenced the bactericidal effect obviously, which not only confirmed the bactericidal mechanism of catalytic oxidation but also provided evidence for the synergistic effect between Ag and Al2O3 on the catalyst surface.     

纳米Pt/巯基丁二酰胺铜修饰电极的制备及其电催化活性

利用电沉积法将纳米Pt固定在巯基丁二酰胺铜(II)自组装金电极(Au/CuL)表面, 制备了一种纳米催化电极(Au/CuL/nano Pt). 分别以扫描电子显微镜(SEM)、原子力显微镜(AFM)、光电子能谱(XPS), 表面红外光谱(FT-IR)及电化学交流阻抗(EIS)对电极表面形貌进行了表征, 并采用循环伏安法(CV)研究了它的电化学性质. 结果表明, CuL具有良好的电化学活性并对H2O2的还原具有电催化作用, 纳米Pt可以显著增强这种催化性能. 在30 ℃、0.02 mol·L-1 PBS缓冲液(pH=6.0)中检测H2O2, 在0.00125-0.16 mmol·L-1浓度范围呈现线性响应, 相关系数为0.9960(信噪比为3), 检测极限为0.3 μmol·L-1. 该电极对H2O2电流响应灵敏度高(0.312 mA·cm-2·mmol-1·L)、检测迅速(4.3 s)、稳定性好(对46 μmol·L-1和2.8 mmol·L-1的H2O2连续测10 次, 变异系数分别为3.1%和3.9%; 保存70 d后对10 μmol·L-1 H2O2的响应为初始响应的95%).     

不锈钢基/β-PbO2-TiO2-Co3O4复合镀层制备及其性能表征

使用直流复合电沉积方法制备不锈钢基β-PbO2、TiO2掺杂β-PbO2、Co3O4掺杂β-PbO2、TiO2和Co3O4共掺杂β-PbO2复合镀层材料.采用SEM、EDS、XRD和电化学测试等对复合电极进行形貌、成分、组成和催化活性表征,并且将不锈钢基/β-PbO2-TiO2-Co3O4电极应用到锌电积实验中.结果表明,添加Co3O4能提高PbO2电极的催化活性;添加TiO2可以起到细化晶粒,增大比表面积的作用;不锈钢基β-PbO2-TiO2-Co3O4复合镀层阳极与Pb-Ag合金阳极相比,锌电积槽电压降低为2.97V,电流效率提高到91.2％,使用寿命延长.     

Ag2S2O7/Ag2O纳米颗粒异质结构的制备及其太阳光全光谱光催化降解应用

Ag2O是优良的感光材料,很少作为光催化材料,而常被用作光催化材料的共催化剂.此外,由于Ag2O禁带宽度窄,且可有效吸收近红外光,因而不能用于全太阳光谱的光催化应用中.同时很少被用作NIR催化剂.本文中不仅研究了纳米Ag2O颗粒的UV-Vis光催化性能,而且还系统探究了其NIR光催化活性.由于在紫外线和可见光的照射下,Ag2O纳米颗粒易发生光还原失活,因而对Ag2O表面硫化处理,使其表面上生长Ag2S2O7层以形成Ag2S2O7/Ag2O异质结,探究了该异质结UV-Vis光催化活性及其光催化循环稳定性;同时,考察了其近红外光催化及其重复使用性能.利用沉淀法成功制备了Ag2O纳米颗粒,并通过在其表面部分硫化处理得到Ag2S2O7,成功构筑Ag2S2O7/Ag2O异质结构,并研究了该Ag2S2O7/Ag2O异质结构UV-Vis-NIR光催化降解有机污染物性能.研究表明,Ag2O纳米颗粒在光子能量较低的NIR照射条件下具有较强的光催化活性,但UV-Vis照射下,虽然Ag2O具有光催化活性,但易发生光还原生成单质银,降低其光催化稳定性;Ag2S2O7/Ag2O纳米异质结,虽然在UV-Vis-NIR范围内光催化活性略降于Ag2O,但稳定性显著提高,总体来看,Ag2S2O7/Ag2O异质结构在全光谱催化方面更具优势.这主要是由于Ag2O表面部分硫化得到的Ag2S2O7纳米颗粒,且二者之间能带匹配促进了光生载流子分离,同时Ag2O表面的Ag2S2O7颗粒直接吸收能量较高的UV-Vis,进而保护内部Ag2O,抑制了其自身还原,可显著提高Ag2S2O7/Ag2O异质结在UV-Vis-NIR催化活性及稳定性.实验结果分析表明,Ag2S2O7/Ag2O异质结纳米颗粒在UV-Vis-NIR条件下均具有稳定且高效的光催化活性,其主要原因为:(1)具有窄带隙的Ag2O可有效拓宽该异质结的光谱吸收;(2)Ag2S2O7/Ag2O异质结能带匹配可有效促使光生载流子分离;(3)Ag2O颗粒表面的Ag2S2O7纳米颗粒可有效提高Ag2S2O7/Ag2O异质结纳米颗粒的光化学稳定性,尤其是在UV-Vis条件下的化学稳定性.Ag2O纳米颗粒受到光照(UV-Vis-NIR)激发后产生电子-空穴对,由于Ag2S2O7与Ag2O能带位置的匹配,Ag2O导带的光生电子注入Ag2S2O7的导带;而Ag2S2O7价带的光生空穴注入Ag2O的价带.Ag2O表面的Ag2S2O7颗粒可有效捕捉电子,从而阻止Ag2O产生的电子-空穴对复合,进而提高光催化活性;同时当光子能量较高(UV以及部分短波长的Vis)时,Ag2O表面的Ag2S2O7颗粒直接吸收该部分光能,进而保护内部Ag2O发生自身还原,因此,Ag2S2O7/Ag2O异质结纳米颗粒在UV,Vis及NIR条件下均具有稳定且高效的光催化活性,在高效利用全光谱光催化降解有机污染物方面具有较大的潜力.     

Al2O3负载Ag催化剂的杀菌作用

 考察了空气中Al2O3负载的Ag催化剂(Ag/Al2O3和AgCl/Al2O3)对大肠杆菌(E.coli)的杀灭作用. 结果表明,负载Ag的催化剂的杀菌效果明显好于Al2O3. 在空气中,催化剂上溶出的Ag+对细菌的重金属毒性可以忽略. Ag/Al2O3, AgCl/Al2O3和Al2O3在有氧和无氧条件下的杀菌效果表明, Ag促进了催化剂表面分子态氧向活性氧转化,活性氧通过氧化作用破坏E.coli 的细胞膜,从而提高了催化剂的杀菌能力. 扫描电镜结果证实在催化剂表面E.coli细胞的破坏是从细胞膜开始的.     

Ag/Fe_3O_4/rGO纳米复合材料的制备及抗菌性能

以四水合氯化亚铁和硝酸银为原料,硼氢化钠为还原剂,氧化石墨烯(GO)为载体,通过原位还原法制备了具有磁分离功能的银/四氧化三铁/还原氧化石墨烯(Ag/Fe_3O_4/rGO)纳米复合抗菌材料.采用X射线粉末衍射仪(XRD)、X射线光电子能谱仪(XPS)、透射电子显微镜(TEM)等对复合材料进行了表征.结果显示,Fe_3O_4和Ag纳米颗粒均匀分布在rGO片层上.复合材料的饱和磁化率(Ms)为40.5 A·m~2·kg·(-1),表明其具有较强的磁性,将其与菌液混合后,在磁场作用下10 min即可吸附沉降完成磁分离.以大肠杆菌(E.coli)和金黄色葡萄球菌(S.aureus)为实验菌株,通过琼脂扩散法评价了复合材料的抗菌性能.结果表明,该复合材料具有良好的抗菌效果,对E.coli和S.aureus的抑菌圈直径分别为18 mm和13 mm,最低抑菌浓度值(MIC)分别为50 mg/L和80 mg/L,最低杀菌浓度值(MBC)分别为30 mg/L和50 mg/L.     

电沉积Al/Pb-Ag阳极在电积锌过程中的耐腐蚀性

采用电沉积的方法在甲基磺酸镀液中制备了一种新型的锌电积Al/Pb-0.23%Ag阳极。 腐蚀实验和电化学分析显示,Al/Pb-0.23％Ag阳极与传统Pb-0.25％Ag阳极相比,具有较低的腐蚀速率,较高的腐蚀电位和较低的腐蚀电流密度,较高的电催化活性;金相显微镜、扫描电子显微镜和X射线衍射分析显示,Al/Pb-0.23％Ag阳极的晶粒细小、致密,极化48 h后有PbSO4、α-PbO2和β-PbO2生成。     

吸附法制备CuO-Ag/SiO2纳米复合物

利用吸附法原位制备CuO/SiO2、CuO-Ag/SiO2纳米复合物,研究了不同吸附质体系中预负载的纳米Ag粒子对CuO的影响。结果表明:Ag粒子对CuO的影响因吸附质的不同而不同。以Cu(Ac)2为吸附质,纳米Ag几乎没有影响;以NaOH为吸附质,纳米Ag使得CuO的晶粒粒径增大。这一结果与铜物种对Ag晶粒粒径的影响规律完全不同。通过比较不同吸附质的吸附行为,Cu(OH)2与硅胶表面的相互作用被认为是导致这一现象的原因。     

Electrochemical fabrication of metal/organic/metal junctions for molecular electronics and sensing applications

A simple electrochemical approach was used for fabricating electrode/metal nanowire/(molecule or polymer)/electrode junctions for sensing or molecular electronics applications. The procedure for fabricating these molecule-based devices involves electropolymerization of phenol or chemisorption of alkanethiols on one set of electrodes (E1) and electrodeposition of Ag metal nano/microwires on a second electrode (E2) which is ～5 μm away from E1. Under appropriate deposition conditions, Ag nanowires grow from E2 and cross over to E1, forming a E1/(molecule or polymer)/Ag nanowire (NW)/E2 junction. The junction resistance was controlled by (1) electrodepositing polyphenol of varied densities on E1 and (2) assembling alkanethiols of different chain lengths on E1. Ag NWs at high resistance E1/polyphenol/Ag NW/E2 junctions functionalized with Pd monolayer protected clusters (MPCs) responded fast and reversibly to H(2) concentrations as low as 0.11% in a nitrogen carrier gas by a resistance decrease, likely due to volume expansion of the Pd nanoparticles, demonstrating the use of these electrochemically fabricated junctions for gas sensing applications.     

甲醇脱氢制无水甲醛的高活性Ag-SiO_2-Al_2o_3催化剂

采用溶胶－凝胶法制备了甲醇直接脱氢制无水甲醛的新型高活性催化剂Ag- SiO_2-Al_2O_3，并考虑了银负载量、焙烧温度及反应温度等对催化剂活性的影响 。XRD结果表明，反应前观察不到银的晶相峰，反应后出现Ag(111)，Ag(200)，Ag (220)，Ag(311)及Ag(222)的特征银晶相峰，SEM结果与XRD吻合得很好。该种特异 结构的催化剂具有对甲醇直接脱氢制甲醛的优异性能，其甲醇转化率达到95.0%， 甲醛得率也高达81.2%，超过己有的文献报道。     

纳米TiO2膜用于光催化氧化测定化学需氧量的研究

A photocatalytic oxidation method for determination of chemical oxygen demand （COD） using nano-TiO2 film, based on the use of a nano-TiO2-Ce（SO4）2 system and electrochemical detection, was proposed. The technique was originated from the direct determination of the Ce（Ⅲ） concentration change resulting from photocatalytic oxidation of organic compounds. Ce（Ⅲ）, which was produced by photocatalytic reduction of Ce（SO4）2, could be measured at a multi-walled carbon nanotubes （MWNT） chemically modified electrode （CME）. The COD values by this method were calculated from the differential pulse voltammetry （DPV） current of Ce（Ⅲ） at the CME. Under the optimal operation conditions, the detection limit of 0.5 mg·L^-1 COD with the linear range of 1-600 mg·L^-1 was achieved. This method was also applied to determination of various COD of ground water and wastewater samples. The resuits were in good agreement with those from the conventional COD methods, i.e., permanganate and dichromate ones.     

Synthesis, characterization, and electrochemical properties of Ag2V4O11 and AgVO3 1-D nano/microstructures

We report on the synthesis, characterization, and electrochemical properties of Ag(2)V(4)O(11) nanowires, alpha-AgVO(3) microrods, and beta-AgVO(3) nanowires that were synthesized through a simple and facile low-temperature hydrothermal approach without any template or catalyst. It was found that by simply controlling the hydrothermal reaction parameters such as pH and dwell time, the transformation of alpha-AgVO(3) microrods to beta-AgVO(3) nanowires were readily achieved through a "ripening-splitting model" mechanism. Electrochemical measurements revealed that the as-prepared Ag(2)V(4)O(11) nanowires, alpha-AgVO(3) microrods, and beta-AgVO(3) nanowires exhibited high discharge capacities and excellent high-rate dischargeability. In particular, the beta-AgVO(3) nanowires have much higher capacity above 3 V than that of alpha-AgVO(3) microrods, Ag(2)V(4)O(11) nanowires, and commercial Ag(2)V(4)O(11) bulk. The mechanisms for electrochemical lithium intercalation of the AgVO(3) nanostructures were also discussed. It is anticipated that the novel Ag(2)V(4)O(11) and AgVO(3) one-dimensional nano/microstructures are promising cathode candidates in the application of primary lithium ion batteries for implantable cardioverter defibrillators (ICDs).     

Y_2O_3负载金属Cu在催化甲醛水溶液制氢反应中的Y_2O_3载体效应

采用NaBH_4还原法将纳米金属Cu负载在Y_2O_3上.通过X射线衍射(XRD)、X射线光电子能谱(XPS)、透射电子显微镜(TEM)和测定氢氧根在Y_2O_3和Cu上的吸附等手段对样品进行了表征.结果表明,Y_2O_3表面存在一层薄的Y(OH)3,能优先吸附OH-使其在Y_2O_3表面"富集";金属Cu以纳米粒子形式负载在Y_2O_3上.在碱性甲醛溶液中考察了Y_2O_3负载Cu(Cu/Y_2O_3)的催化性能.结果表明,在低碱度条件下,相对于未负载纳米Cu的Y_2O_3,Cu/Y_2O_3具有较高的产氢活性.当氢氧化钠浓度为0.050 mol/L时,在氮气气氛下Cu/Y_2O_3产氢量约为未负载纳米Cu的7.8倍;而在空气气氛下约为4.3倍.在2种气氛下,Cu/Y_2O_3产氢的最佳氢氧化钠浓度均为0.25 mol/L.这可归结为Y_2O_3表面对OH-的"富集"效应,使其表面产生更多的活性物种CH2(OH)O-(甲二醇负离子).相对于未负载纳米Cu的Y_2O_3,Y_2O_3负载Cu提高了催化剂的稳定性,其原因是Y_2O_3负载阻止了Cu粒子在反应过程的生长.     

Ti/α-PbO2/β-PbO2电极电化学降解2-氯酚

采用电化学沉积法在Ti基底上制备了复合电极Ti/α-PbO2/β-PbO2,扫描电镜结果表明电极呈现由β-PbO2小晶体组成的菜花状微观形貌.所制电极在电化学降解环境污染物2-氯酚时表现出较高的电催化效率、较好的电极稳定性和较长的电极寿命.用正交实验优化了电化学降解2-氯酚的实验条件.在最优的实验条件(2-氯酚初始浓度50 mg/L,电解质0.1 mol/L Na2SO4,温度35oC,阳极电流密度20 mA/cm2)下电化学降解180 min后,2-氯酚的去除率达100%.动力学结果表明, Ti/α-PbO2/β-PbO2电极上2-氯酚的电化学氧化符合准一级动力学过程.     

氨基酸多金属氧酸盐纳米粒子复合膜的制备及抗菌活性

用水热微乳法制备了Keggin结构(CTA)0.2(HGly)2.8［PMo12O40］·nH2O(1) 纳米粒子(nano-1), 并通过元素分析, XPS, IR, XRD, TEM和CV进行表征. 利用层接层自组装技术, 将已制备的纳米粒子装配成纳米复合膜, 用紫外-可见光谱监测膜的生长, 用电化学方法分析膜的成分. 测定了纳米粒子对致病Escherichia coli(E. coli)的拮抗性， 结果显示, 纳米粒子及其复合膜具有显著的抗菌活性.     

三维有序大孔SiO2中的纳米银

A multi-step process was used for preparation of three-dimensionally ordered macroporous (3DOM) SiO2, in which fully accessible Ag nanoparticles are incorporated. The method involves the processes of assembly of polystyrene colloidal crystal, preparation of 3DOM SiO2, and incorporation of Ag nanoparticles within 3DOM SiO2 through in situ Tollens‘ reaction. XRD, SEM and EDXS determination show that the Ag particles deposited on the macroporous walls in nano dimension. The results indicate that lower concentration of silver ammoniate and for-maldehyde in the solution is favorable for forming a very narrow size distribution and uniform shape of nanoparticles. However, the higher the concentration of the solution and the more the loading times, the larger the possibility to form un-uniform particles. Ag nanoparticles can be sintered into larger and spheral particles by calcination at 600℃, but can resist sintering owing to their high dispersivity when loading amount is small. The study provided a simple approach to tailor Ag/3DOM SiO2 composite materials with desired morphology and size of Ag particles within the macropores.     

纳米TiO2电极在不同介质中的电化学行为

纳米电极;电催化;纳米TiO2电极在不同介质中的电化学行为;循环伏安法;循环方波伏安法