改性凹凸棒石黏土负载纳米铁/钯双金属对4,4′-二溴联苯醚的去除研究

通过分步还原法制备了改性凹凸棒石黏土负载纳米零价铁/钯双金属复合材料(OA-Fe/Pd),并通过X射线衍射(XRD)、透射电镜(TEM)和傅里叶变换红外吸收光谱(FTIR)对其进行表征.以改性凹凸棒石黏土(OA)和改性凹凸棒石黏土负载纳米零价铁材料(OA-Fe)为对照,探讨了OA-Fe/Pd对溶液中4,4′-二溴联苯醚(BDE15)的去除性能,并考察了Pd负载量、材料投加量、BDE15初始浓度、溶剂条件和溶液初始pH对去除BDE15的影响.XRD和TEM表征结果表明纳米零价Fe/Pd双金属颗粒较均匀地分散在OA表面,双金属颗粒粒径小于100 nm.去除动力学实验结果表明OA-Fe/Pd对溶液中BDE15的去除性能显著高于OA和OA-Fe.OA-Fe/Pd对BDE15的去除速率随着Pd负载量和材料投加量的增大而增大,而随着BDE15初始浓度、溶剂中四氢呋喃的比例、溶液初始pH的增大而减小.OA-Fe/Pd对BDE15的去除动力学过程符合准一级动力学方程.OA-Fe/Pd对BDE15的去除机制主要为还原脱溴降解.在适宜的条件下,BDE15可被OA-Fe/Pd完全还原脱溴为联苯醚(DE).     

纳米级Pd/Fe双金属体系对水中2,4-二氯苯酚脱氯的催化作用

 利用化学沉淀法制备了纳米级Fe和纳米级Pd/Fe双金属催化剂,研究了它们对2,4-二氯苯酚(2,4-DCP)还原脱氯的催化性能. 结果表明,纳米级颗粒具有较高的比表面积和表面反应活性,其BET比表面积可达12.4 m2/g,当Pd/Fe用量为6 g/L时,2,4-DCP脱氯率达到90%以上. 脱氯效率与pH值、温度、钯含量和Pd/Fe投加量等因素有关. 2,4-DCP在脱氯过程中先生成2-氯苯酚和4-氯苯酚,最终生成苯酚,而少量的2,4-DCP可直接降解成苯酚.     

亚微米级Cu0/Fe3O4复合物多相催化过一硫酸盐降解有机污染物

过一硫酸盐催化活化技术因其可产生强氧化性活性氧化物种,可快速氧化降解并矿化有机污染物的优异性能而备受关注.本文成功制备了亚微米级Cu0/Fe3O4复合物,发现其能多相催化过一硫酸盐产生单线态氧降解有机污染物.首先,以CuCl2·2H2O,FeCl2·4H2O和FeCl3·6H2O为铜源和铁源,水合肼为还原剂,采用水热法在180oC反应24 h制备了亚微米级磁性Cu0/Fe3O4复合物.表征结果显示,所制材料为Cu0和Fe3O4的复合物,颗粒大小约为220 nm;单一相Cu0和Fe3O4晶体粒径分别为33.8和106.2 nm,而Cu0/Fe3O4复合物中Cu0和Fe3O4晶体粒径分别减为20.8和31.9 nm.这表明Cu0和Fe3O4复合降低了Cu0和Fe3O4晶体粒径,有利于Cu0和Fe3O4的分散.BET测试结果表明,Cu0/Fe3O4复合物比表面积为4.6 m2/g,与Cu0颗粒的(4.2 m2/g)相当,但远小于Fe3O4的(15.6 m2/g).制备的Cu0/Fe3O4复合物可有效催化过一硫酸盐产生单线态氧降解罗丹明B、亚甲基蓝、金橙II、苯酚和对氯酚.当Cu0/Fe3O4复合物的用量为0.1 g/L,过一硫酸盐浓度为0.5 mmol/L和初始pH为7时,Cu0/Fe3O4复合物可在30 min内完全降解20μmol/L的罗丹明B、亚甲基蓝、金橙II以及0.1 mmol/L的苯酚和对氯酚.对比试验显示,在相同条件下,Cu0和Fe3O4颗粒分别可以降解28%和20%的罗丹明B.这表明Cu0/Fe3O4复合物中的Cu0和Fe3O4晶体在催化过一硫酸盐降解污染物的反应中具有协同作用,这主要来源于Cu0/Fe3O4复合物中Cu0和Fe3O4的晶体粒径变小和更好的分散.采用分光光度法测定了降解反应液中铜和铁离子的溶出量.当Cu0/Fe3O4复合物的用量为0.1 g/L,过一硫酸盐浓度为0.5 mmol/L和初始pH为7时,反应60 min后,降解液中铜和铁离子的浓度分别为0.22和0.1 mg/L,仅占复合物中总铜和总铁量的1.1%和0.2%,表明Cu0/Fe3O4复合物具有较强的化学稳定性.所制Cu0/Fe3O4复合物具有超顺磁性,借助磁场实现快速分离回收,可循环利用五次,表明其优越的催化稳定性.通过加入乙醇和叠氮化钠,考察了Cu0/Fe3O4复合物催化活化过一硫酸盐体系中的活性氧化物种.发现100 mmol/L乙醇的加入对污染物的降解无明显影响,而加入同等量的叠氮化钠可完全抑制污染物的降解,表明Cu0/Fe3O4复合物催化活化过一硫酸盐产生的主要活性氧物种为单线态氧.采用电子顺磁共振谱进一步证实了单线态氧的生成.基于以上研究,Cu0/Fe3O4复合物催化活化过一硫酸盐的机理为Cu0/Fe3O4作为一个电子媒介加速过一硫酸盐和污染物之间的电子转移,从而导致污染物被快速降解.该反应机理不同于常见的金属催化过一硫酸盐产生硫酸根和羟自由基的反应机理.我们推测,电导性优良的Cu0在此催化反应中起着关键性作用.本催化方法可作为一种绿色的氧化技术用于环境污染物的氧化降解处理.     

Cu/活性炭催化剂：水合肼还原制备及催化甲醇氧化羰基化

以活性炭为载体,水合肼为还原剂制备了负载型Cu/活性炭催化剂,考察了水合肼/硝酸铜物质的量的比对催化甲醇气相氧化羰基化性能的影响,并采用XRD、XPS、H2-TPR和SEM等手段对催化剂进行了表征。结果表明,不加入还原剂水合肼时,催化剂中仅有CuO;随着水合肼/硝酸铜物质的量的比的增加,二价铜逐步被还原为Cu2O和/或单质Cu0,未被还原的Cu(OH)2在催化剂干燥过程中分解形成分散态CuO存在于催化剂表面。当水合肼/硝酸铜物质的量的比为0.75时,催化剂的催化性能最好,碳酸二甲酯的时空收率为120.62 mg.(g.h)-1,选择性为74.51%,甲醇转化率达到3.88%。在93 h反应时间内,催化剂都保持了较高的反应活性和选择性。此时铜物种以Cu2O和分散态CuO为主,Cu2O是主要的活性物种。     

载体表面性质对Cu2O/AC催化剂结构和活性的影响

采用活性炭(AC)载体浸渍醋酸铜, 然后热分解制备甲醇气相氧化羰基化合成碳酸二甲酯的无氯Cu2O/AC催化剂. 用硝酸或氨水处理活性炭后, 其表面的化学性质发生了变化, 从而影响了Cu2O/AC催化剂的结构和催化活性. 实验结果表明, 硝酸或氨水改性后的活性炭表面不仅有新的含氮基团产生, 而且含氧基团C-O-C, C-O和CO-O增加, CO基团明显减少或消失. 其中, 含氮基团的供电子效应和富余的CO-O基团使负载在载体上的CuⅡ更容易被还原成CuⅠ, 有利于获得组分单一且分散较好的Cu2O负载型催化剂, 从而显著地提高了催化活性. 氨水改性的活性炭更加有利于活性物种Cu2O的分散, 能够进一步改善催化性能, 在n(CO)∶n(MeOH)∶n(O2)=4∶10∶1, SV=5600 h-1条件下, 甲醇转化率达到7.0%, DMC的时空收率为145.1 mg/(g·h), 基于甲醇的选择性为68.7%.     

Fe柱撑海泡石负载Cu催化剂：结构特点及其C3H6选择性催化还原NO催化性质

通过羟基铁离子柱撑将海泡石(Sep)改性成Fe柱撑海泡石(Fe-PILSEP),使用浸渍法(IM)将Cu负载在Fe-PILSEP上,制得不同铜含量的xCu/Fe-PILSEP催化剂。通过X射线衍射(XRD)、N2-吸附/脱附、H2-程序升温还原(TPR)和X射线光电子能谱(XPS)等对样品进行表征,并测定其对丙烯选择性催化还原NO的催化活性。N2-吸附/脱附和TGA结果表明,Fe-PILSEP的比表面积和孔体积较海泡石原矿Sep极大地增加,热稳定性也明显优于Sep。XRD和XPS结果表明,在xCu/Fe-PILSEP催化剂上同时存在Fe3+/Fe2+和Cu2+/Cu+不同氧化态的氧化物,而且Fe与海泡石之间存在相互作用,Fe和Cu之间存在电子迁移。H2-TPR结果表明,xCu/Fe-PILSEP催化剂上存在不同聚集状态的氧化铜物种。xCu/Fe-PILSEP催化剂的丙烯选择性催化还原NO的催化活性明显优于Fe-PILSEP催化剂,这可能与Fe和Cu的氧化还原性有关。xCu/Fe-PILSEP的催化活性与Cu负载量相关,其中10Cu/Fe-PILSEP催化剂显示出最高的活性,这与其高的比表面积、孔体积和氧化还原性能,及其具有更多有利于HC-SCR反应的孤立Cu2+((Cu2+)i)物种有关。     

Fe2O3含量对Cu-Fe/铝土矿水煤气变换催化剂结构和性能的影响

利用具有高比表面积和介孔结构的改性铝土矿为载体,采用并流共沉淀法制备不同Fe2O3含量的Cu-Fe/铝土矿催化剂。以水煤气变换反应为探针反应,考察了催化剂性能。利用X射线荧光元素分析(XRF)、X射线粉末衍射(XRD)、H2程序升温还原(H2-TPR)、CO程序升温脱附(CO-TPD)和X射线光电子能谱(XPS)等对催化剂进行了表征。结果表明:负载的Fe2O3能显著提高CuO/改性铝土矿催化剂的水煤气变换活性特别是热稳定性能,且随负载的Fe2O3含量增加而提高,当负载量为20%时达到最佳。其原因是负载的Fe2O3和CuO之间发生了相互作用,形成了类似于CuFe2O4复合氧化物,且随负载的Fe2O3含量的增加而增强,这种相互作用同时促进了CuO和Fe2O3的还原,抑制了CuO的烧结,进而提高了催化剂的性能。     

微米级花状结构铜/聚乙烯吡咯烷酮的制备及其抗菌性能

采用液相还原的方法,以聚乙烯吡咯烷酮(PVP)为修饰剂,氯化铜为前驱体,水合肼为还原剂,成功制备了微米级Cu/PVP花状结构.采用扫描电子显微镜和X射线粉末衍射仪分析了所得样品的形貌与结构;利用差热分析测定了样品的热稳定性,并采用肉汤稀释法测试了其抗菌性能.结果表明,所制备的样品具有由多个Cu/PVP圆片组装而成的直径为6μm的花状结构,其形貌依赖于反应条件.与此同时,花状结构的Cu/PVP对金黄色葡萄球菌和大肠杆菌具有明显的抗菌作用,相应的最小抑菌浓度(MIC)和最小杀菌浓度(MBC)分别为:41.25mg/L、82.5mg/L,以及20.63mg/L、82.5mg/L.与单一Cu纳米微粒相比,花状结构的Cu/PVP复合物的抗菌持久性明显较好.     

Fe-Ni/TiO2纳米管阵列电极的制备、表征及光电催化还原五氯酚活性

采用阳极氧化法和浸渍电沉积联用法制备了不同负载量的Fe-Ni/TiO2纳米管阵列电极. 通过扫描电子显微镜(SEM)、 X射线光电子能谱(XPS)和电化学测量等手段对样品的微观形貌、 晶体结构和光电响应等特性进行分析. 考察了在0.6 V偏压下, 所制备的电极对五氯酚的光电催化还原性能. 结果表明, 适量的Fe和Ni纳米颗粒的负载, 降低了TiO2纳米管阵列光生电子-空穴对的复合几率; 浸渍电沉积5次的Fe-Ni/TiO2纳米管阵列电极光电催化还原降解五氯酚的效率为91.35%, 明显高于TiO2纳米管阵列电极.     

Cu负载Fe柱撑钠化海泡石: 结构特点及其丙烯选择性催化还原NO性质研究

采用羟基铁离子柱撑钠化海泡石改性后, 以浸渍法制备了铜负载铁柱撑钠化海泡石Cu/Fe-NaPILCS催化剂, 作为比较以浸渍法制备了铁负载钠化海泡石(Fe-NaSep), 铜负载钠化海泡石(Cu-NaSep)和铜铁负载钠化海泡石(Cu/Fe-NaSep)催化剂. 并将它们应用于C₃H₆选择性催化还原NO的反应(C₃H₆-SCR). 通过X射线衍射仪(XRD)、TGA-DTG分析、N₂-等温吸附/脱附、H₂-程序升温还原(TPR)和X射线光电子能谱仪(XPS)等技术对样品进行表征. N₂-等温吸附/脱附和TGA-DTG分析结果表明, Fe-NaPILCS的比表面积和孔体积较海泡石原矿具有较大的增加, 热稳定性也明显提高|XRD和XPS结果表明, 在Cu/Fe-NaPILCS催化剂上同时存在Fe^3＋/Fe^2＋和Cu^2＋/Cu^＋不同氧化态的氧化物种, 在Cu和Fe之间存在电子迁移. H₂-TPR结果表明, Cu/Fe-NaPILCS催化剂上存在大量的孤立铜离子物种(isolated Cu^2＋-ions, (Cu^2＋)_i). Fe柱撑钠化海泡石负载的Cu/Fe-NaPILCS催化剂的催化活性明显优于未柱撑海泡石负载的Cu/Fe-NaSep催化剂, 这可能与Cu/Fe-NaPILCS具有较大的比表面积、孔体积和更优的氧化还原性能, 及其具有更多有利于C₃H₆-SCR反应的(Cu^2＋)_i物种有关.     

Dechlorination of chlorophenols by magnesium-silver bimetallic system

More than 85% of 10 mg L(-1) of pentachlorophenol (PCP) was removed by magnesium/silver (206/1.47 mM) bimetal system in the presence of acetic acid. Dechlorination was found to be sequential and phenol was identified as the ultimate hydrocarbon skeleton along with some accumulation of tetra-, tri-, and dichlorophenols. The dechlorination reaction was found to follow second-order kinetics. Lower PCP removal efficiency (35%) was observed when the reaction was carried out in the absence of acid using Mg(0)/Ag system. When the reaction was conducted using Mg(0) alone in the presence of acid, substantial sorption of PCP occurred with very low efficiency of PCP dechlorination. Dechlorination studies on 10 mg L(-1) initial concentrations of 2,3,4,6-tetrachlorophenol (2,3,4,6-TeCP) and 2,4,5-trichlorophenol (2,4,5-TCP), under identical conditions as to PCP, revealed that dechlorination efficiency and reaction rate constants decrease with decreasing number of chlorine atoms on the target compound. A correlation (R(2)>0.9) between the dechlorination rate constants and E(LUMO) for chlorophenols was obtained.     

改性高粱秸秆对Cu(Ⅱ)吸附性能及热力学和动力学分析

研究了改性高粱秸秆对Cu(Ⅱ)的吸附性能。结果表明,pH对改性高粱秸秆吸附Cu(Ⅱ)影响显著。常温(30℃)下,对20mL pH=5.0的20mg/L的Cu(Ⅱ)溶液,改性高粱秸秆投加量0.35g,吸附时间60min,Cu(Ⅱ)去除率可达84.82%。改性高粱秸秆对Cu(Ⅱ)的吸附符合Langmuir吸附等温方程和准二级动力学模型,吸附过程的△G0<0,△H0>0且仅为4.31kJ/mol,△S0>0说明改性高粱秸秆对Cu(Ⅱ)的吸附是以单分子层物理吸附为主的自发吸热过程。     

Catalytic Dechlorination of Chlorobenzene in Water by Pd／Fe System

Chlorobenzene was dechlorinated by Pd/Fe bimetallic system in water through catalytic reduction. The dechlorination rate increases with increase of bulk loading of Pd due to the increase of both the surface loading of the Pd and the total surface area. For conditions with 0.005% Pd/Fe, 45% dechlorination efficiency was achieved within 5 h. The dechlorinated reaction is believed to take place on the bimetal surface in a pseudo-first-order reaction, with the rate constant being 0.0043 min^-1.     

铁基双金属材料还原降解三溴甲烷的研究

本文制备了Cu/Fe和Pd/Fe两种铁基双金属材料,考察它们对溴仿(CHBr_3)的还原去除效果。结果表明,溴仿的还原去除效果都随双金属材料投加量的增加而增加;溶液中H~+浓度越高,越有利于还原反应的进行;溶解氧的存在会对还原去除反应产生抑制作用。双金属材料与溴仿的还原去除反应包括直接还原和间接还原两种途径。Pd和Cu通过与零价铁组成原电池结构加快了零价铁在水中的腐蚀速度,从而增强了零价铁对溴仿的直接还原去除效果。Pd与Cu相比,具有更高的氢过电位,氢气更容易在Pd的表面生成,而氢气也可以作为还原剂,取代溴仿分子中的溴原子,完成还原脱卤。因此,Pd/Fe双金属材料对溴仿的还原去除效果要好于Cu/Fe双金属材料。     

Oxygen, carbon, and sulfur segregation in annealed and unannealed zerovalent iron substrates

Finely ground and pretreated iron substrates known as "zerovalent iron" or "Fe0" are used as reductants in the environmental remediation of halogenated hydrocarbons, and the composition of their surfaces significantly affects their reactivity. Samples of unannealed and annealed (heat-treated under H2/N2) zerovalent iron were analyzed using X-ray photoelectron spectroscopy (XPS) and Auger electron spectroscopy (AES). Surface concentration of the iron and of the impurities observed by XPS and AES, carbon, chlorine, sulfur, and oxygen, were measured before and after soaking in trichloroethylene (TCE) and in water saturated with TCE (H2O/TCE) to simulate chlorocarbon remediation conditions. Samples pretreated by annealing at high temperature under H2 contained less iron carbide. The carbide contaminant was evident in both iron and carbon XPS spectra, with binding energies of 709.0 and 283.3 eV for the Fe 2p3/2 and C 1s, respectively. The annealed Fe0 surface also contained more sulfur. The carbide concentration was essentially unchanged by TCE and H2O/TCE exposure, whereas the sulfur decreased in proportion to chlorine adsorption following the dechlorination reaction. While oxygen concentration is initially lower on the annealed substrate surface, it rapidly increased during the model TCE remediative treatment process and thus does not represent a significant effect of the annealing process on surface reactivity.     

Impact of membrane immobilization on particle formation and trichloroethylene dechlorination for bimetallic Fe/Ni nanoparticles in cellulose acetate membranes

The use of membrane immobilization to carry out the batch dechlorination of trichloroethylene (TCE) using bimetallic Fe/Ni (4:1, Fe to Ni) nanoparticles in cellulose acetate membranes is examined using modeling of transport phenomenon based on experimental results. Membranes are synthesized using both gelation and solvent evaporation techniques for phase inversion. The reduction of metal ions within cellulose acetate phase-inversion membranes was accomplished using sodium borohydride reduction to obtain up to 2 wt % total metals. Characterization of the mixed-matrix structure reveals a bimodal particle distribution ranging between 18 and 80 nm within the membrane cross section. The distribution is the result of changes in the morphology of the cellulose acetate support. The diffusivity and linear partitioning coefficient for the chlorinated organic were measured and are 2.0 x 10(-8) cm2.s-1 and 3.5 x 10(-2) L.g-1, respectively. An unsteady-state model for diffusion through a membrane with reaction was developed to predict experimental results with an error of only 7.2%. The error can be attributed to the lack of the model to account for loss of reactivity through pH effects, alloy effects (bimetallic ratio), and oxidation of nanoparticles. Simulations were run to vary the major transport variables, partitioning and diffusivity, and determine their impact on reaction kinetics. Of the two, diffusivity was less significant because it really only influences the time required for maximum TCE partitioning to the membrane to be achieved and has no effect on the limiting capacity of the membrane for TCE. Therefore, selection of an appropriate support material is crucial for development of highly reactive mixed-matrix membrane systems.     

Green Synthesis of Fe and Fe/Pd Bimetallic Nanoparticles in Membranes for Reductive Degradation of Chlorinated Organics

Membranes containing reactive nanoparticles (Fe and Fe/Pd) immobilized in a polymer film (polyacrylic acid, PAA-coated polyvinylidene fluoride, PVDF membrane) are prepared by a new method. In the present work a biodegradable, non-toxic -"green" reducing agent, green tea extract was used for nanoparticle (NP) synthesis, instead of the well-known sodium borohydride. Green tea extract contains a number of polyphenols that can act as both chelating/reducing and capping agents for the nanoparticles. Therefore, the particles are protected from oxidation and aggregation, which increases their stability and longevity. The membrane supported NPs were successfully used for the degradation of a common and highly important pollutant, trichloroethylene (TCE). The rate of TCE degradation was found to increase linearly with the amount of Fe immobilized on the membrane, the surface normalized rate constant (k(SA)) being 0.005 L/m(2)h. The addition of a second catalytic metal, Pd, to form bimetallic Fe/Pd increased the k(SA) value to 0.008 L/m(2)h. For comparison purposes, Fe and Fe/Pd nanoparticles were synthesized in membranes using sodium borohydride as a reducing agent. Although the initial k(SA) values for this case (for Fe) are one order of magnitude higher than the tea extract synthesized NPs, the rapid oxidation reduced their reactivity to less than 20 % within 4 cycles. For the green tea extract NPs, the initial reactivity in the membrane domain was preserved even after 3 months of repeated use. The reactivity of TCE was verified with "real" water system.     

Synthesis and Characterization of Cu Decorated Zeolite A@Void@Et-PMO Nanocomposites for Removal of Methylene Blue by a Heterogeneous Fenton Reaction

Hydrothermal synthesized nano zeolite A has been encapsulated with ethyl bridged periodic mesoporous organosilica(Et-PMO) shell tlirougli a simple modified Stober method and an organosilane-directed growth-induced etching strategy, the obtained yolk-shell structured A@Et-PMO nanocomposite(YS-A@Et-PMO) was further functionalized by the impregnation of copper ions, realizing the composite material with hierarchical porous and catalytic properties. The morphology and metal content of the Cu/A and Cu/YS-A@Et-PMO were fully characterized. As compared to tlie parent material, the composite Cu/YS-A@Et-PMO has an efficient adsorption and catalytic degradation performance on methylene blue(MB), the removal efficiency reached as high as 95% of 60 mg/L MB within 10 min. These novel structured porous composites may have great potential application for the removal of organic dye including waste effluents.     

石墨烯负载零价纳米铁材料的合成及去除水中Cr(VI)的研究

以石墨粉为原料,采用改良Hummers方法合成石墨烯,然后通过液相还原法制备出石墨烯负载纳米铁材料(Graphene-supported nanoscale zero-valent iron,G-nZVI),借助扫描电子显微镜(SEM)、红外光谱分析仪(FTIR)进行表征,并以G-nZVI为反应材料,研究其对水体中Cr(VI)的去除效率,结果显示:室温下,当G-nZVI投加量为0.4g/L,Cr(VI)的初始浓度为20 mg/L,初始pH值为3.0时,Cr(VI)的去除率在2h内可以达到95%以上。G-nZVI具有磁性,使用后可通过外加磁力除去,以防对水体的二次污染,具有较好的应用前景。     

血红蛋白在壳聚糖修饰碳纳米管上的电化学特性及对过氧化氢的电催化分析

用壳聚糖对多壁碳纳米管进行修饰,构建了一种用于固定血红蛋白的新型复合材料,并研究了血红蛋白在该碳纳米管上的电化学性质及其对过氧化氢的电催化活性.扫描电镜结果表明,壳聚糖修饰的多壁碳纳米管呈单一的纳米管状,并能均匀分散在玻碳电极表面.紫外光谱分析表明血红蛋白在该复合膜内能很好地保持其原有的二级结构.将该材料固定在玻碳电极上后,血红蛋白能成功地实现其直接电化学.根据峰电位差随着扫描的变化,计算得到血红蛋白在壳聚糖修饰的碳纳米管膜上的电荷转移系数为0.57,表观电子转移速率常数为7.02 s-1.同时,该电极对过氧化氢显示出良好的催化性能,电流响应信号与H2O2浓度在1.0×10-6 ～1.5×10-3 mol/L间呈线性关系,检出限为5.0×10-7 mol/L.修饰电极显示了良好的稳定性.