In-situ preparation and electrochromic properties of TiO2/PTPA-HTAN core-shell nanocomposite film

A new star-shaped structure conjugated microporous polymers, poly (2,8,14-tri[4-diphenyl-benzene]-hexaazatrinaphthylene) (PTPA-HATN), was designed and in-situ electrochemically polymerized on the surfaces of FTO electrodes with a directional alignment TiO₂ nanorod array to obtain TiO₂/PTPA-HATN core-shell nanocomposite films. Compared with the PTPA-HATN film, the TiO₂/PTPA-HATN composite film exhibits higher optical contrast and faster response time, with contrast of 57% at 783 nm, coloring time of 3.62 s and discoloring time of 2.55 s (43%, 4.63 s and 4.77 s for PTPA-HATN film, respectively). After 400 cycles, the contrast of nanocomposite film decreased by 28%, while the PTPA-HATN film basically lost its electrochromic properties. A simple three-layer EC prototype device based on TiO₂/PTPA-HATN nanocomposite film constructed with hydrogel electrolyte clearly shows color changes at different voltages. On the one hand, the formation of core-shell porous nanostructure of TiO₂/PTPA-HATN composite film provides a larger ion doping/de-doping interface, shortening the average diffusion length of ions. On the other hand, the large indented polymer-nanorods contact interface makes it difficult for the polymer to detach from the electrode, thus significantly improving the cyclic stability of the composite film.     

Electrochemically Assisted Cycloaddition of Carbon Dioxide to Styrene Oxide on Copper/Carbon Hybrid Electrodes: Active Species and Reaction Mechanism

A novel electrochemically assisted cycloaddition process is proposed, in which highly efficient coupling of CO₂ with styrene oxide (SO) can be achieved to form styrene carbonate (SC) as a high-value-added product. A series of Cu catalysts with different morphologies and chemical states were fabricated on carbon paper (CP) by using in-situ electrodeposition, and the sample with nano-dendrimer structure was found to exhibit a relatively high activity of 74.8 % SC yield with 92.7 % SO conversion under gentle reaction conditions, thus showing its potential for practical applications. The relatively high electrochemically active surface area and charge transfer ability of dendrimer-like Cu benefited the electrochemical reaction. In particular, the Cu²⁺ species that were formed in situ during the reaction played a vital role in enhancing the activity and selectivity of the proposed Cu/CP hybrid catalyst. Cu²⁺ atoms served as active sites that can not only electrochemically activate CO₂ but also facilitate the ring opening of SO. Mechanistic analysis suggested that the reaction followed electrochemical and liquid-phase heterogeneous paths, which provide a new green and sustainable route for efficient utilization of CO₂ resources for fine chemical electrosynthesis.     

Voltammetric and spectroscopic studies of water/formamide ratios in the production of the cerium (III) hexacyanoferrate (II) nanoparticles

The present study describes the simple and fast preparation of Cerium (III) hexacyanoferrate (II) (CeHCF) solid nanoparticles at three different water/formamide (%) ratios used as solvent (v/v) (100:0, 80:20, 0:100). CeHCF nanoparticles (Nps) were characterized by fourier transform infrared pectroscopy (FTIR), x-ray diffraction (XRD), scanning electron microscopy (SEM), zeta potential and cyclic voltammetry (CV). Electrodes modified with CeHCF presented a well-defined redox pair with formal potential (E^o′) of approximately 0.29 V (vs. Ag/AgCl(sat) attributed to the Fe^{2 +}/Fe³⁺ redox pair in the presence of cerium (III)). The Nps in the three systems investigates, presents a random size distribution to different surface, where most were distributed between 20 and 160 nm. Considering the three investigated systems, only CeHCF-1 (100:0) was sensitive to L-dopamine, presenting a linear signal region as a function of L-dopamine concentrations, with a limit of detection (LD) of 0.125 mmol L⁻¹, limit of quantification (LQ) of 0.419 mmol L⁻¹ and amperometric sensitivity (S) of 148.16 μA mmol L⁻¹.     

Silver/graphene–polypyrrole composite for levosimendan detection

This study used a facile method to develop a novel silver/Graphene–polypyrrole (Ag/G–PPy)-modified electrode that can be used as an electrochemical sensor for levosimendan detection. The properties of the synthesized Ag/G–PPy-modified electrode were examined through field-emission scanning electron microscopy, x-ray diffraction, and transmission electron microscopy. The Ag/G–PPy-modified electrode exhibited satisfactory current signals toward levosimendan concentrations ranging from 0.21 to 6.88 μM and exhibited a low detection limit (0.12 μM). Accordingly, the proposed electrode can serve as a simple and inexpensive electrochemical sensor for levosimendan detection.     

基于羧基化聚吡咯-氯化血红素和点触发链置换反应信号放大的电化学生物传感器检测转基因作物中CaMV35S序列

为适应快速增长的转基因生物(GMOs)安全评价与管理的需求,高效、可靠的转基因检测技术研究与应用的重要性日益凸显。该文采用一步法合成了羧基化聚吡咯(cPPy)与氯化血红素(Hemin)的纳米复合物(cPPy-hemin),并以其为信号标签合成了一种DNA双链结构功能化的纳米信标(DNA-cPPy-hemin)。利用cPPy-hemin增强的模拟酶催化活性,结合点触发链置换反应(TSDR)信号放大策略,制备了一种新型电化学基因传感器用于转基因成分的灵敏检测。通过信号探针(Ps)与模板链(Ts)、辅助链(As)结合形成DNA双链体结构中的-NH2功能化cPPy-hemin,制备Ts/As/Ps-cPPy-hemin双链DNA结构的纳米信标。在目标花椰菜花叶病毒35S启动子(CaMV35S)序列和燃料链(Fs)存在下,TSDR过程释放出的Ps-cPPy-hemin与固定在电化学沉积金纳米粒子修饰GCE表面上巯基化的DNA捕获探针(Cs)相结合,利用cPPy-hemin对H₂O₂的模拟酶催化产生的电信号,可实现对CaMV35S的定量检测。在最优条件下...     

An Electrochemical Sensor Fabricated by Sonochemical Approach for Determination of the Antipsychotic Drug Haloperidol

A nanocomposite (Ho₂O₃NPs/BNT) was synthesized by decorating holmium(III)oxide nanoparticles (H₂O₃NPs) on bentonite (BNT) through a realizable sonochemical approach for the electrochemical detection of haloperidol (Hlp). A glassy carbon electrode was modified with this nanocomposite. The Ho₂O₃NPs/BNT modified electrode outperformed bare and other modified electrodes in terms of electrochemical performance for Hlp detection in a pH 8.0 phosphate buffer. The proposed electrochemical platform showed a wide linear range (0.01 μM–24 μM), low detection limit (2.4 nM), and high sensitivity by square wave voltammetry. In addition, the proposed electrochemical sensor met the clinical criteria in terms of stability, selectivity, and repeatability.     

基于中空多孔金纳米/石墨烯复合纳米材料的葡萄糖氧化酶直接电化学及其生物传感研究

采用溶液相牺牲模板法制备中空多孔金纳米粒子（HPAuNPs）,并将该材料与还原氧化石墨烯（rGO）复合,用于葡萄糖氧化酶（GOx）在玻碳电极（GCE）表面的有效固定,构建GOx/HPAuNPs/rGO/GCE传感界面。利用扫描和透射电镜、X射线光电子能谱、X射线衍射谱、红外光谱及电化学等方法对材料的形貌与结构,GOx的固定化过程,以及传感器的直接电化学和电催化性能进行表征。结果表明,HPAuNPs和rGO的协同作用能有效促进GOx与电极之间的直接电子转移（DET）。基于GOx/HPAuNPs/rGO/GCE对葡萄糖的良好电催化性能,该方法有效实现了对葡萄糖的高灵敏度检测,其电流响应的线性范围为0.05～7.0 mmol/L,检出限（S/N=3）为16μmol/L。该传感器具有良好的选择性、重现性及稳定性,对实际样品血清中血糖的测定结果令人满意,回收率为98.0%～103%,相对标准偏差不大于5.0%。     

乙烯在钯圆盘电极的电化学氧化研究（英文）

由于巨大的潜在市场,乙烯的电化学氧化受到愈来愈多的关注。目前,主流的电化学氧化法仍以依赖于氧化还原媒介的介导氧化法为主,而这些媒介的使用在电解过程中产生大量的腐蚀性中间体,使其实际应用受到阻碍。直接电氧化法可有效规避此问题,但又受到低活性和低选择性的限制。在本工作中,我们针对目前最先进的钯催化直接氧化体系,在中性条件下开展了一系列电化学研究,以对该过程的机理获取更深入的认识。在氮气和乙烯氛围下,钯电极的循环伏安谱图有显著区别。我们发现电解过程中生成的Pd(Ⅱ)物种在乙烯氛围下可绕过原本的电化学还原路径,通过一个化学步还原为Pd(0),因此可能是乙烯氧化的活性位点。Pd(Ⅱ)物种所对应的还原峰也因此可作为乙烯吸附的数量的指标。通过电化学脉冲序列的设计,我们在钯催化剂上识别了两种具有不同吸附强度的乙烯,其强、弱吸附模式所对应的电荷转移比例约为0.3:1。弱吸附的乙烯在钯电极表面表现出可逆的吸脱附行为,而具有强吸附模式的乙烯无法通过物理过程脱附,可能指向到乙烯深度氧化过程。这项工作为进一步设计高性能乙烯直接电氧化催化剂提供了设计思路和方向。     

Praseodymium Doped Dysprosium Oxide-carbon Nanofibers Based Voltammetric Platform for the Simultaneous Determination of Sunset Yellow and Tartrazine

A platform based on praseodymium doped dysprosium oxide-carbon nanofibers modified electrode was constructed for the simultaneous determination of SY and TAR. SEM, EDX and XRD techniques were utilized for characterizing the proposed material. The voltammetric behaviour and properties of SY and TAR were gradually improved at materials in order from CNFs to Dy₂O₃−CNFs and Pr₆O₁₁@Dy₂O₃−CNFs. The working range was found to be 1.0×10⁻⁹–3.5×10⁻⁸ M and 1.5×10⁻⁹–4.0×10⁻⁸ M for SY and TAR, respectively. The value of LOD was 3.12×10⁻¹⁰ M and 5.35×10⁻¹⁰ M for SY and TAR, respectively. The platform (Pr₆O₁₁@Dy₂O₃−CNFs/GCE) was successfully applied to the electroanalysis of samples.     

Amperometric sandwich-type aptasensor based on peroxidase mimetic Au@Pt for the carcinoembryonic antigen

For sensitive analysis of cancer biomarker carcinoembryonic antigen (CEA), an amperometric sandwich-type aptasensor is proposed based on a signal amplification strategy of Au@Pt bimetallic nanoprobes. As the excellent catalytic activity to hydrogen peroxide (H₂O₂), core-shell Au@Pt nanoparticles are employed as nanoprobes by conjugating directly with the secondary aptamer of CEA (Apt-II). Due to the synergic recognition effect of dual aptamers and the excellent catalytic activity of nanoprobes, this amperometric sandwich-type aptasensor for CEA exhibits high specificity and good sensitivity with a limit of detection of 0.31 ng/mL, along with a wide linear range from 0.1 ng/mL to 100 ng/mL.