Eastman—AQ／四硫富瓦烯修饰碳纤维微秀电极

利用新型摄影了了聚合物膜将以富瓦烯修饰到电极表面上，并研究了修饰电极的电化学行为，研究了浸泡时间、扫描速度和支持电解质对修饰电极性能的影响；循环伏安法、计时电流法和交流阻抗法表明四硫富瓦烯在膜中的扩展是控制步骤。四硫富瓦烯在膜中的第一对氧化还的峰呈现可逆的，单电子反应。用循环伏安法测得了ＴＴＦ＋ＴＴＦ＋＋＝２ＴＴＦ＋的反应的平衡常数。     

Nafion—四硫富瓦烯修饰蜡浸石墨电极的葡萄糖传感器

本文用四硫富瓦烯（ＴＴＦ）作为酶与电极之间的电子传递体，通过牛血清蛋白和戊二醛交联剂，把葡萄糖化氧化酶固定在Ｎａｆｉｏｎ－ＴＴＦ修饰石墨电极上，最后在电极修饰一层Ｎａｆｉｏｎ膜，制备成葡萄糖传感器。Ｎａｆｉｏｎ膜不仅能防止四硫富瓦燃流失，而且能氢抗坏血酸，尿酸等电活生物质阻挡在电极外，防止其干扰，同时具有防污性能。通过实验表明ＴＴＦ＾＋，ＴＴＴ＾２＾＋都能够氧化葡萄糖氧化酶中的辅酶（ＦＡＤＨ２）。     

以四硫富瓦烯为电子媒介体的电流式葡萄糖传感器

用四硫富瓦烯作为酶与电极之间的电子传递体，通过Ｎａｆｉｏｎ水溶液把葡萄糖氧化酶固定在Ｎａｆｉｏｎ－ＴＴＦ修饰玻碳电极上，最后在电极上装饰一层Ｎａｆｉｏｎ膜，制备成葡萄糖传感器。Ｎａｆｉｏｎ膜不仅能防止四硫富瓦烯流失，而且能把抗坏血酸、尿酸等电活性物质阻挡在电极外，防止其干扰，同时具有防污性能。通过实验表明ＴＴＦ＾＋１、ＴＴＴ＾＋２都能够氧化葡萄糖氧化酶中的辅酶。该传感器的线性范围为３．０×１０＾－     

新型三(四硫富瓦烯)环蕃的合成和性质

利用四(3'-碘丙硫基)四硫富瓦烯和四硫富瓦烯二钠盐反应合成新的三(四硫富瓦烯)环蕃, 并通过循环伏安法和化学氧化法分别对其氧化还原性质和紫外光谱进行了研究.     

四硫富瓦烯为电子媒介体的葡萄糖生物传感器的研究

本采用四硫富瓦烯（ＴＴＦ）作为葡萄糖氧化酶与玻碳电极之间的电子媒介体，把葡萄糖氧化酶因定在Ｎａｆｉｏｎ－ＴＴＦ修饰电极上，制成葡萄糖生物传感器。用这种传感器测定人体血清中葡萄糖的含量，其线性范围在４．０×１０＾－５～１０＾－３ｍｏｌ／Ｌ之间，响应时间为２０ｓ。该传感器具有选择性、重现性好，灵敏度高等优点。     

新型I型五聚四硫富瓦烯衍生物的合成和性质

利用2,3-二(2'-氰乙基硫基)-6,7-二烷硫基四硫富瓦烯在甲醇钠的作用下消除一个保护基团生成四硫富瓦烯单钠盐,与1,4-二(氯甲基)苯反应,形成单桥-双(四硫富瓦烯)衍生物,生成的单桥-双(四硫富瓦烯)衍生物再次在甲醇钠的作用下消除剩下的保护基团,形成单桥-双(四硫富瓦烯)衍生物二钠盐,最后与四(3'-碘丙硫基)四硫富瓦烯反应形成新型I型五聚TTF衍生物,并通过循环伏安法和化学氧化法分别对其氧化还原性质和紫外光谱进行了研究.     

新型I型五聚四硫富瓦烯衍生物的合成和性质

利用2,3-二(2'-氰乙基硫基)-6,7-二烷硫基四硫富瓦烯在甲醇钠的作用下消除一个保护基团生成四硫富瓦烯单钠盐,与1,4-二(氯甲基)苯反应, 形成单桥-双(四硫富瓦烯)衍生物, 生成的单桥-双(四硫富瓦烯)衍生物再次在甲醇钠的作用下消除剩下的保护基团, 形成单桥-双(四硫富瓦烯)衍生物二钠盐, 最后与四(3'-碘丙硫基)四硫富瓦烯反应形成新型I型五聚TTF衍生物, 并通过循环伏安法和化学氧化法分别对其氧化还原性质和紫外光谱进行了研究.     

新型四四硫富瓦烯环蕃的合成和性质

利用2,3-二(2-氰基乙硫基)-6,7-二烷硫基四硫富瓦烯在甲醇钠的作用下消除一个保护基团生成四硫富瓦烯单钠盐, 与1,4-二氯甲基苯反应, 形成“单桥”-双(四硫富瓦烯)衍生物, 生成的“单桥”-双(四硫富瓦烯)衍生物再次在甲醇钠的作用下消除剩下的保护基团, 形成“单桥”-双(四硫富瓦烯)衍生物二钠盐, 最后与二溴代烷反应形成新型四四硫富瓦烯环蕃, 并通过循环伏安法和化学氧化法分别对其氧化还原性质和紫外光谱进行了研究.     

采用四硫富瓦烯为黄嘌呤氧化酶的电子传递体的次黄嘌呤传感器

采用四硫富瓦烯（ＴＴＦ）作为黄嘌呤氧化酶与玻碳电极之间的电子传递体，通过牛血清白蛋白和戊二醛交联剂，把黄嘌呤氧化酶固定在Ｎａｆｉｏｎ－ＴＴＦ修饰玻碳电极上，制备成次黄嘌呤传感器。该传感器的线性范围为１．０×１０－５～７．５×１０－４ｍｏｌ／Ｌ，响应时间小于６０ｓ。     

电化学石英晶体微天平研究六氟亚铁铜膜修饰电极及其离子效应

利用电化学石英晶体微天平（ＥＱＣＭ）手段，结合循环伏安法，计量电流法对六氰亚铁铜（ＣｕＨＣＦ）膜修饰电极及其在不同水溶液中的离子交换机制进行了研究。结果表明：通过循环伏安法，在Ｐｔ电极上可以牢固地形成ＣｕＨＣＦ膜。在氧化还原过程中，不仅是阳离子，阴离子也参与了在ＣｕＨＣＦ膜中的传输     

复合聚合物修饰的粉末微电极及其对亚硝酸根还原的催化

本论文简述用Nafion_Os(bpy) 3 2 + /PVP复合膜修饰的乙炔黑粉末微电极 ,以亚硝酸根还原为模型反应 ,实现从复合修饰及扩大电极比表面两方面改善电极性能的思路 .结果表明 ,它同时显示Nafion_Os(bpy) 3 2 + /PVP修饰电极对NO2 -及NO+ 双重富集并再生活性粒子NO+ 、防止中继体流失、加速膜中中继体传输、改变反应途径等复合修饰电极的多种功能以及粉末微电极的高比表面、高液相传质速度以及薄层效应的特性 .与平面修饰电极及裸粉末微电极相比 ,它明显提高了酸性溶液中亚硝酸根还原的可逆性、呈数量级地提高稳态极限电流密度以及NO2 -的检测指标 .     

聚氯乙烯膜修饰碳微电极的研制及应用

采用浸涂流延法制得ＰＶＣ膜修饰碳微电极,用Ｋ３Ｆｅ（ＣＮ）６的循环伏安图考察了电极的电化学性能,并用此电极建立了环境水样中痕量汞的阳极溶出伏安法测定。在０．０６ｍｏｌ／Ｌ ＫＳＣＮ＋０．０１ｍｏｌ／ＬＫＣｌ介质中,富集电位－０．８０Ｖ,搅拌富集时间３００ｓ,扫描电压范围－０．２０～０．４０Ｖ,扫描速率３１４ｍＶ／ｓ,咄峰电流与Ｈｇ＾２＋浓度在０．０１～２．０ｍｇ／Ｌ的范围内有良好的线性关系,本电极     

PVC膜修饰粉末微电极的研制及应用

聚合物具有催化、导电和选择分离等功能,将其与电极合为一体作为新的电极材料,可为改善固体电极的灵敏度、选择性和重现性提供一种新的手段［１,２］．我们用流延法［３］制得ＰＶＣ选择性渗透膜,覆盖于粉末微电极表面,制成了ＰＶＣ膜修饰粉末微电极．该电极性能稳定...     

Fabrication and Use of Dual‐function Iridium Oxide Coated Gold SECM Tips. An Application to pH Monitoring above a Copper Electrode Surface during Nitrate Reduction.

The fabrication of a gold microelectrode modified with iridium oxide film (IrO_x) and its use as tip with a dual function in SECM experiments is reported. The defective structure of the coating onto the microelectrode surface was used as strategy to combine the advantages of both amperometric (for current‐distance determination) and potentiometric (for pH sensing) SECM operation modes. Approach curves, using oxygen and hexaammineruthenium(III) as redox mediators, were obtained without significant loss of the performance and reproducibility of the potentiometric pH response. This allowed the precise positioning of the proposed tip above a substrate in SECM experiments and, subsequently, to monitor pH at the substrate surface. The IrO_x modified microelectrode was applied successfully in SECM experiments involving the local proton consumption during the nitrate reduction at a copper cathode surface.     

Preparing of Iridium Oxide Film Modified Microelectrode as an Amperometric Detector in FIA for Determination of Epinephrine

Abstract

Iridium oxide film modified microelectrode with a tip diameter of 25 µm was constructed using anodically grown iridium oxide film. The iridium oxide film, which was formed at the tip of the iridium wire by cyclic voltammetry in dilute sulfuric acid, showed excellent catalytic activity towards the oxidation of epinephrine. The stability and electrochemical properties of iridium oxide film modified microelectrode along with catalytic oxidation of epinephrine was studied. An oxidation peak was observed at 0.28 V. The electron‐transfer number (n) was 2. The iridium oxide film modified microelectrode was used as a detector in flow injection system for determination of epinephrine. Under the optimized conditions, the calibration curve was linear in the concentration range of 1.0×10^?8 to 1.0×10^?5 mol/l for epinephrine, with a detection limit of 1.0×10^?9 mol/l. The iridium oxide film modified microelectrode was used for direct determination of the epinephrine in human serum samples. The flow injection analysis was precise detection method of epinephrine and time saving device.     

电化学掺铜(Ⅱ)类普鲁士蓝膜修饰电极的制备及其对亚硝酸根的测定

研究在普鲁士蓝(PB)修饰膜中,利用电化学方法掺杂Cu2+制备的掺Cu2+类普鲁士蓝(Cu-PB)修饰膜.通过循环伏安和交流阻抗实验,考察了制备的Cu-PB修饰膜的电化学性质和对NO-2的响应特性,并与PB修饰膜进行了比较.研究表明,掺Cu2+后不仅改变了PB膜的内部结构,其电化学性能也发生了明显变化,PB修饰膜对NO-2无电催化作用,而Cu-PB修饰膜对亚硝酸根具有明显的电催化作用.在pH=5.85的PBS缓冲溶液中,NO-2的浓度在1.0×10-2～5.0×10-5 mol/L范围内与还原峰电流呈良好的线性关系(r=0 9983); 检出限(3S/N)为1.0 μmol/L.本法用于实际样品的测定,回收率为97.5%～104%,结果令人满意.     

同多酸和杂多酸修饰微电极的电化学研究 Ⅶ.磷钒钼杂多酸薄膜修饰微电极和杂多酸/聚苯胺薄膜修饰微电极的制备和电化学性质

本文详细描述了磷钒钼杂多酸（PV2Mo10）极薄膜修饰碳纤维（CF）微电极和PV2Mo10／聚苯胶（PAn）薄膜修饰微电极的制备及其电化学性质。     

Carbon Cavity Microelectrode for Electrical Wiring of Enzyme by Insoluble Electroactive Species in Aqueous Media

The carbon cavity microelectrode (CME), exhibiting a volume of 4×10^?6 cm³, offers a genuine alternative for immobilizing and connecting enzymes in aqueous electrolytes by powder of insoluble redox materials. In the present work, the electrochemical behavior of two redox species such as ferrocene (Fc) and tetrathiafulvalene (TTF) was investigated with CME to evaluate their potentialities in the electrical wiring of enzymes. For this purpose, powder of two enzymes, glucose oxidase (GOx) and horseradish peroxidase (HRP), was independently mixed with an insoluble redox material and forced to fill the single micro cavity of a carbon electrode covered by an inert insulator. The presence of the electroactive species, as well as the enzyme wiring was investigated by cyclic voltammetry. The amperometric detection of glucose was carried out by potentiostating the TTF/GOx and the Fc/GOx microelectrodes at 0.25 and 0.35 V respectively. The amperometric detection of H₂O₂ by the TTF/HRP microelectrode was performed at ?0.1 V vs. SCE.     

Amperometric glucose sensor using tetrathiafulvalene in Nafion gel as electron shuttle

An amperometric mediated sensor for glucose has been contrived by using bovine serum albumin and glutaraldehyde to immobilize glucose oxidase on a Nafion-tetrathiafulvalene (TTF) modified electrode. It is further coated by Nafion. The inner Nafion membrane can prevent leaking of tetrathiafulvalene; the outer Nafion film serves as a barrier to electroactive anionic interferents such as ascorbate and urate and protects the biosensor from fouling agents. The experiment shows that TTF⁺ and TTF²⁺ can oxidize the reduced flavin adenine dinucleotide (FADH₂) of glucose oxidase. The biosensor responds to glucose in less than 50 s and its calibration curve is linear from 3.0 × 10⁻⁴ to l.0 × 10⁻² M.     

基于薄膜电极的细胞电融合芯片

构建了一种薄膜电极阵列结构的细胞电融合芯片, 通过多聚物微通道底/顶层凸齿状的微电极, 以及多聚物微通道侧壁上溅射形成的一层离散式金属薄膜电极, 共同形成离散式"三明治"微电极结构. 该微电极结构可在微通道内部形成与传统凸齿状电极相似的非均匀分布的梯度电场, 通过介电电泳效应进行细胞控制及排队. 利用多聚物在芯片上填充了传统凸齿状电极的凹陷区, 克服了细胞在凹陷区无法有效排队与融合的缺点. 在芯片上利用K562细胞开展了基于介电电泳效应的细胞排队实验及基于可逆性电穿孔效应的电融合实验, 结果表明该芯片能够较好地实现细胞排队及融合, 融合所需控制电压低至10 V左右. 细胞排队率达99%以上, 几乎无细胞在绝缘物填充区(传统凸齿电极芯片的凹陷区)滞留, 细胞两两排队高于60%, 细胞融合效率约为40%, 比传统的细胞电融合方法和凸齿电极芯片有较大提高.