铁氰化镍的磁性纳米粒子合成及化学修饰电极的制备

将镍粒子表面功能化,合成了磁性纳米铁氰化镍（NiHCF）粒子,制备了磁性NiHCF修饰磁控玻碳电极。 在pH=7.4的磷酸盐缓冲溶液中,磁性NiHCF纳米粒子修饰电极对水合肼氧化有显著的催化作用,NiHCF的氧化峰电流与水合肼浓度在0~1.29×10-4 mol/L范围内呈良好的线性关系（安培法）,检出限为2.1×10-8 mol/L。 研究了磁性NiHCF粒子修饰电极对水合肼的电化学响应以及电极的性能,并将其应用于水样中肼的测定。 该修饰电极具有灵敏度高、选择性好、电极易更新、稳定性好和制作简单等优点。     

电还原氧化石墨烯-铁氰化钴修饰电极对肼的测定

本文提出了一种新的水合肼的测定方法。利用静电作用,在氧化石墨烯(GO)表面吸附一层均匀分散的Co2+形成GO-Co2+复合物,通过恒电位法电还原复合物中的GO,再利用循环伏安法将吸附的Co2+转化为铁氰化钴(CoHCF),制得电还原的氧化石墨烯-铁氰化钴修饰玻碳电极(ERGO-CoHCF/GCE)。采用扫描电子显微镜(SEM)对修饰电极表面进行了表征。研究了水合肼在该修饰电极上的电化学行为及在不同电极上的电流响应。结果表明:ERGO-CoHCF/GCE对肼具有很好的电催化氧化作用,其浓度与氧化峰电流呈良好的线性关系。     

纳米分子筛LTA包裹Ni-Salen配合物为修饰碳糊电极用于电催化氧化肼反应

采用柔性配体法将Ni-salen配合物包裹在纳米分子筛LTA的超笼中,用来修饰碳糊电极制得Ni(Ⅱ)-SalenA/CPE,并采用循环伏安法、计时电流法和计时库仑法考察了该电极电催化氧化0.1 mol/L NaOH溶液中肼反应性能.首先采用无有机模板剂法合成纳米分子筛LTA,并用各种技术进行了表征.XRD和粒径分析结果分别显示LTA晶体的平均粒径为56.1和72nm.在Ni(Ⅱ)-SalenA/CPE电极氧化还原位上水合肼催化氧化反应电子转移系数为0.64,速率常数为1.03×105cm3/(mol·s).电催化反应机理研究表明,水合肼氧化反应通过它与Ni3+(Salen)O(OH)反应或直接进行电氧化反应.阳极峰电流与扫描速率的平方根呈线性关系,表明反应受扩散控制,水合肼的扩散系数为1.18×10?7cm2/s.结果表明,Ni(Ⅱ)-SalenA/CPE对水合肼氧化反应表现出高的电催化活性,这是由于纳米分子筛LTA的多孔结构以及Ni(Ⅱ)-Salen的存在.最后研究了水合肼在碱性溶液中Ni(Ⅱ)-SalenA/CPE电极上的氧化反应机理,发现其为四电子过程,第一个电子转移反应为速率控制步骤,然后是一个三电子过程,产生环境友好的最终产物氮气和水.     

纳米分子筛LTA包裹Ni-Salen配合物为修饰碳糊电极用于电催化氧化肼反应（英文）

采用柔性配体法将Ni-salen配合物包裹在纳米分子筛LTA的超笼中,用来修饰碳糊电极制得Ni(Ⅱ)-Salen A/CPE,并采用循环伏安法、计时电流法和计时库仑法考察了该电极电催化氧化0.1 mol/L Na OH溶液中肼反应性能.首先采用无有机模板剂法合成纳米分子筛LTA,并用各种技术进行了表征.XRD和粒径分析结果分别显示LTA晶体的平均粒径为56.1和72nm.在Ni(Ⅱ)-Salen A/CPE电极氧化还原位上水合肼催化氧化反应电子转移系数为0.64,速率常数为1.03×10~5 cm~3/(mol·s).电催化反应机理研究表明,水合肼氧化反应通过它与Ni~(3+)(Salen)O(OH)反应或直接进行电氧化反应.阳极峰电流与扫描速率的平方根呈线性关系,表明反应受扩散控制,水合肼的扩散系数为1.18×10~(-7)cm~2/s.结果表明,Ni(Ⅱ)-Salen A/CPE对水合肼氧化反应表现出高的电催化活性,这是由于纳米分子筛LTA的多孔结构以及Ni(Ⅱ)-Salen的存在.最后研究了水合肼在碱性溶液中Ni(Ⅱ)-Salen A/CPE电极上的氧化反应机理,发现其为四电子过程,第一个电子转移反应为速率控制步骤,然后是一个三电子过程,产生环境友好的最终产物氮气和水.     

水滑石负载的钯纳米粒子对水合肼的电催化氧化

利用共沉淀方法制备了载体水滑石(LDH), 通过离子交换法将PdCl2₄^- 插入水滑石层间, 再用水合肼将其还原, 制备得到了水滑石负载的分散状钯纳米粒子(LDH-Pd⁰). 利用X射线衍射(XRD)、透射电镜(TEM)和X射线电子能谱(XPS)等手段对所得样品进行了表征, 结果表明钯纳米粒子能很好地分散在水滑石上. 将该纳米材料修饰的玻碳电极(GCE)用于水合肼的电催化氧化, 该修饰电极表现出很好的电化学催化活性. 用循环伏安法(CV)、计时库仑法(CC)和计时安培法(i-t)对修饰电极的催化活性、有效表面积和水合肼的催化氧化机理等进行了研究. 结果表明水合肼在-0.1 V附近有明显的氧化峰, 在1.0×10^-5-2.0×10^-4 mol·L^-1范围内, 阳极峰电流与水合肼浓度间有良好的线性关系, 其检测限为9.5×10^-7 mol·L^-1. 计算得到GCE, LDH-Pd⁰/GCE 和LDH/GCE电极活化面积分别为0.02089, 0.02762 和0.02496 cm². 推知水合肼的氧化过程有4 电子和4 质子参与, 并且其在电极上的反应是受扩散控制的不可逆过程.     

水合肼在多壁碳纳米管修饰电极上的电化学行为及测定

报道了水合肼在碳纳米管修饰电极上的电化学行为以及水合肼测定的新方法。与裸玻碳电极相比,多壁碳纳米管修饰玻碳电极使水合肼的氧化峰电流显著提高,同时氧化过电位降低,测定灵敏度大为提高。优化了底液、pH、修饰剂量等测定条件。在最佳条件下,该修饰电极测定水合肼的线性范围为2.9×10-8~9.8×10-4mol/L,线性相关系数为-0.9945,检出限为1.0×10-9mol/L。对1.0×10-4mol/L的水合肼平行测定10次的相对标准偏差为4.4%。此方法已用于模拟水样中水合肼的测定。     

水合肼引发烯类单体聚合研究

本文研究了不同结构甲基丙烯酸酯用水合肼作引发剂时的本体及溶液聚合,测定了甲基丙烯酸甲酯(MMA)在乙醇中的聚合反应总活化能及引发活化能,研究了不同水合肼浓度下氧含量与聚合速度的关系,从水合肼存在下单体氧化和聚合的关系,提出并讨论了引发机理。     

肼在有机合成上的应用

肼,N_2H_4(hydrazine)的化学的研究已近九十年,于1875年,Fischer给予命名,到1887年,Curtius才成功的得到游离的肼。肼一般是以两种状态存在,一为无水肼,一为各种浓度的肼的水溶液。在肼的水溶液中,肼是与一分子水缔合着的,称为水合肼,N_2H_4·H_2O(hydrazinehydrate)。一般在有机合成上应用的肼,常为易于制备价格便宜的水合肼,且多采用浓度为85％左右的水合肼水溶液。关于与本文有密切关系的肼的理化性质、高浓度水合肼溶液的制备及肼的含量的测定,讀者可参阅诸专著及文献。肼是一个强还原剂,也是一种亲核性的试剂,它在有机合成上的应用,主要均与这些性质有关。关于肼的有机化学,内容极为丰富和重要,作者拟于另文中综述。肼作为一个试剂,在有机合成上亦极为重要,兹将肼在有机合成上的应用,分为七个方面,加以讨论。     

偶氮二甲酸二异丙酯的合成

以氯甲酸异丙酯、水合肼为主要原料,制备肼-1,2-二甲酸二异丙酯,然后用双氧水氧化制得偶氮二甲酸二异丙酯(DIAD)。 研究确定了最佳的反应条件:在0 ℃以下乙醚溶剂中,水合肼和氯甲酸异丙酯反应2 h,制备肼-1,2-二甲酸二异丙酯;n(肼-1,2-二甲酸二异丙酯)∶n(双氧水)=1:1.1,在-5~5 ℃下反应2 h,双氧水氧化得到偶氮二甲酸二异丙酯,总收率为90.7%,采用红外光谱、核磁共振等技术手段验证了中间体及目标产物结构。     

水合肼选择性还原炔烃至顺式烯烃研究

转移氢化反应是一种条件温和、反应转化率高的还原反应.研究了一系列双烷基和双羟基修饰的炔类化合物,在空气中水合肼的作用下选择性还原为顺式烯烃的方法,其中水合肼作为转移氢化试剂,空气中氧气作为氧化剂,通过氧化反应将肼氧化为二氮烯N_2H_2分子,进而二氮烯N_2H_2分子选择性还原炔烃为顺式烯烃.通过二维核磁共振谱证明了生成的烯烃的构型为顺式结构.     

方波伏安法测定新型修饰多壁碳纳米管糊电极对肼的电催化氧化(英文)

The application of p-aminophenol as a suitable mediator, as a sensitive and selective voltammetric sensor for the determination of hydrazine using square wave voltammetric method were described. The modified multiwall carbon nanotubes paste electrode exhibited a good electrocatalytic activity for the oxidation of hydrazine at pH = 7.0. The catalytic oxidation peak currents showed a linear dependence of the peaks current to the hydrazine concentrations in the range of 0.5–175 μmol/L with a correlation coefficient of 0.9975. The detection limit (S/N = 3) was estimated to be 0.3 μmol/L of hydrazine. The relative standard deviations for 0.7 and 5.0 μmol/L hydrazine were 1.7 and 1.1%, respectively. The modified electrode showed good sensitivity and selectivity. The diffusion coefficient (D = 9.5 × 10–4 cm2/s) and the kinetic parameters such as the electron transfer coefficient (α = 0.7) of hydrazine at the surface of the modified electrode were determined using electrochemical approaches. The electrode was successfully applied for the determination of hydrazine in real samples with satisfactory results.     

Electrocatalytic oxidation and detection of hydrazine at gold electrode modified with iron phthalocyanine complex linked to mercaptopyridine self-assembled monolayer

Electrocatalytic oxidation and detection of hydrazine in pH 7.0 conditions were studied by using gold electrode modified with self-assembled monolayer (SAM) films of iron phthalocyanine (FePc) complex axially ligated to a preformed 4-mercaptopyridine SAMs. The anodic oxidation of hydrazine in neutral pH conditions with FePc-linked-mercaptopyridine-SAM-modified gold electrode occurred at low overpotential (0.35 V versus Ag|AgCl) and the treatment of the voltammetric data showed that it was a pure diffusion-controlled reaction with the involvement of one electron in the rate-determining step. The mechanism for the interaction of hydrazine with the FePc-SAM is proposed to involve the Fe^(III)Pc/Fe^(II)Pc redox process. Using cyclic voltammetry (CV) and Osteryoung square wave voltammetry (OSWV), hydrazine was detected over a linear concentration range of 1.3 × 10⁻⁵ to 9.2 × 10⁻⁵ mol/L with low limits of detection (ca. 5 and 11 μM for OSWV and CV, respectively). At concentrations higher than 1.2 × 10⁻⁴ mol/L the anodic peak potential shifted to 0.40 V (versus Ag|AgCl), and this was interpreted to be due to kinetic limitations resulting from the saturation of hydrazine and its oxidation products onto the redox-active monolayer film. This type of metallophthalocyanine-SAM-based electrode is a highly promising electrochemical sensor given its ease of fabrication, good catalytic activity, stability, sensitivity and simplicity.     

Cobalt Hexacyanoferrate-Modified Electrode for Amperometric Assay of Hydrazine

A graphite electrode modified with cobalt hexacyanoferrate by mechanical immobilization was used for amperometric determination of hydrazine. The modified electrode exhibits good catalytic activity for the oxidation of hydrazine at a reduced overpotential with remarkable sensitivity. The modified electrode showed a linear response for hydrazine in the concentration range of 2.0 × 10^–5 to 2.8 × 10^–4 M. The detection limit was 9.8 × 10^–6 M (S/N = 3). The proposed modified electrode was simple, sensitive, rapid, stable and promising.     

Amperometric flow-injection analysis of hydrazine by electrocatalytic oxidation at cobalt tetraphenylporphyrin modified electrode with heat treatment

Chemically modified electrodes prepared by treating the cobalt tetraphenylporphyrin modified glassy-carbon electrode at 750 degrees (HCME) are shown to catalyze the electrooxidation of hydrazine. The oxidation occurred at +0.63 V vs. Ag/AgCl (saturated potassium chloride) in pH 2.5 media. The catalytic response is evaluated with respect to solution pH, potential scan-rate, concentration dependence and flow-rate. The catalytic stability of the HCME is compared with that of the cobalt tetraphenylporphyrin adsorbed glassy-carbon electrode. The stability of the HCME was excellent in acidic solution and even in solutions containing organic solvent (50% CH(3)OH). When used as the sensing electrode in amperometric detection in flow-injection analysis, the HCME permitted sensitive detection of hydrazine at 0.5 V. The limit of detection was 0.1 ng. The linear range was from 50 ng to 2.4 mug. The method is very sensitive and selective.     

Electrocatalytic oxidation of hydrazine at poly(4,5-dihydroxy-1,3-benzenedisulfonic acid) multiwall carbon nanotubes modified-glassy carbon electrode: Improvement of the catalytic activity

A stable electroactive thin film of poly(4,5-dihydroxy-1,3-benzenedisulfonic acid) was electrochemically deposited at the surface of multiwall carbon nanotubes-glassy carbon electrode. The electrocatalytic oxidation of hydrazine has been studied at the surface of the modified electrode using cyclic voltammetry, chronoamperometry and linear sweep voltammetry as diagnostic techniques. The modified electrode exhibits good electrocatalytic activity for the oxidation of hydrazine with a good sensitivity. Linear calibration range was in the wide concentration range of 10–3540 μM hydrazine with a detection limit of 1.8 μM and a sensitivity of 85.3 nA/μM. A Tafel plot, derived from voltammograms, indicated a one-electron transfer process to be the rate-limiting step and the overall number of electrons involved in the catalytic oxidation of hydrazine was found to be four. The influences of potentially interfering substances were studied. The diffusion coefficient of hydrazine was also evaluated. Finally, the proposed modified electrode was used for the determination of hydrazine in spiked water samples.     

Development of an Electrochemical Sensor Nanoarray for Hydrazine Detection Using a Combinatorial Approach

The combinatorial screening of different metallic nanoparticles as electrocatalysts was investigated and efficiently applied for the detection of hydrazine. In a first step, glassy carbon microspheres decorated with metallic nanoparticles (Au, Pd, and Ag) were abrasively attached on the surface of a basal plane pyrolytic electrode giving a ‘multi–metal’ nanoarray. In a second step, electrodes modified with only one type of metallic nanoparticles allowed the identification of Pd as the unique catalytic material. In addition, a carbon‐epoxy composite electrode loaded with the Pd nanoparticles was then constructed for a practical use. The carbon‐epoxy composite nanoarray electrode was found to have excellent characteristics as for the sensing of hydrazine with a limit of detection of 2 μM.     

Gold Nanoparticles Decorated Graphene as a High Performance Sensor for Determination of Trace Hydrazine Levels in Water

Electrochemical sensors provide a selective, sensitive and an easy approach to detect hazardous substances such as hydrazine. Herein, we investigate a facile route for the fabrication of a nanostructured composite based on Au nanoparticles (AuNPs) decorated graphene and present its sensing performance towards hydrazine. Our strategy involves electrophoretic deposition (EPD) of graphene oxide (GO) on Au substrate to obtain a uniform layer EPD‐GO, followed by electrochemical reduction of GO to yield high quality graphene ERGO and electrodeposition of monodispersed AuNPs on ERGO (AuNPs/ERGO/Au). The modified AuNPs/ERGO/Au electrode was characterized using scanning electron microscopy (SEM) and Fourier transform infrared spectroscopy (FT‐IR) techniques. The sensor exhibited an improved catalytic activity with a peak potential of +87 mV (vs. Ag/AgCl) for hydrazine oxidation. The high performance of this hybrid electrode is due to the presence of a synergistic effect between AuNPs and ERGO at their interface. Insights into the mechanism and kinetics of hydrazine oxidation are withdrawn from varying the voltage scan rate as the reaction is fully irreversible and diffusion‐controlled. The proposed hydrazine sensor showed suitability for nanomolar detection (detection limit of 74 nM), high selectivity in the presence of common ions and efficiency for application in water samples.     

Electrocrystallized Ag nanoparticle on functional multi-walled carbon nanotube surfaces for hydrazine oxidation

4-Aminobenzoic acid was covalently grafted on multi-walled carbon nanotubes (MWNTs) by amine cation radical formation in the electrooxidation process of the amino-containing compound. Then, silver (Ag) nanoparticles were electrocrystallized on 4-aminobenzoic acid monolayer-grafted MWNTs by a potential-step method. The structure and nature of the resulting Ag/MWNT composites were characterized by transmission electron microscopy and X-ray diffraction. The electrocatalytic properties of the Ag/MWNT electrode for hydrazine oxidation have been investigated by cyclic voltammetry, high electrocatalytic activity of the Ag/MWNT electrode can be observed. This may be attributed to the small particle size of the silver particles. The results imply that the Ag/MWNT composites have a good application potential in fuel cells.     

Preparation, Electrochemical Behavior and Electrocatalytic Activity of a Copper Hexacyanoferrate Modified Ceramic Carbon Electrode

A copper hexacyanoferrate modified ceramic carbon electrode （CuHCF/CCE） had been prepared by two-step sol-gel technique and characterized using electrochemical methods. The resulting modified electrode showed a pair of well-defined surface waves in the potential range of 0.40 to 1.0 V with the formal potential of 0.682 V （vs. SCE） in 0.050 mol·dm^-3 HOAc-NaOAc buffer containing 0.30 mol·dm^-3 KCl. The charge transfer coefficient （a） and charge transfer rate constant （ks） for the modified electrode were calculated. The electrocatalytic activity of this modified electrode to hydrazine was also investigated, and chronoamperometry was exploited to conveniently determine the diffusion coefficient （D） of hydrazine in solution and the catalytic rate constant （kcat）. Finally, hydrazine was determined with amperometry using the resulting modified electrode. The calibration plot for hydrazine determination was linear in 3.0 × 10^-6--7.5 × 10^-4 mol·dm^-3 with the detection limit of 8.0 × 10^-7 molodm^-3. This modified electrode had some advantages over the modified film electrodes constructed by the conventional methods, such as renewable surface, good long-term stability, excellent catalytic activity and short response time to hydrazine.