基于掺杂氟的二氧化锡导电玻璃的苏丹红I号电化学降解研究

研究了基于掺杂氟的二氧化锡(FTO)导电玻璃的苏丹红I号电化学降解工艺,考察了电解质浓度、环境酸度、外加电压、初始浓度等因素对苏丹红I号去除率的影响.结果表明,以FTO导电玻璃为阳极,控制电解电压为12 V,对含20 g/L氯化钠的苏丹红I号(0.01 g/L)溶液(p H 9.0)进行电化学降解20 min后,苏丹红I号的脱色率可达到60%.     

Construction of an Amperometric Glucose Biosensor by Immobilization of Glucose Oxidase on Nanocomposite at the Surface of FTO Electrode

Fluorine? tin oxide (FTO) nanostructure was developed on the surface of a glass plate using spray payroliziz method. A new electrochemical biosensor was fabricated based on a layer by layer process. In this process chitosan? Fe₃O₄ (CH? Fe₃O₄) nanocomposite film was prepared at the surface of FTO electrode by dip? coating method. In the next step, the glucose oxidase (GOx) was immobilized on the CH? Fe₃O₄/FTO nanocomposite electrode. The GOx/CH? Fe₃O₄/FTO bioelectrode has a linear range of 10–270 µM and a detection limit of 5 µM. The highest sensitivity was obtained at 1.2 µA mM^?1 cm^?2.     

Structural and electrical properties of fluorine doped tin oxide films prepared by spray-pyrolysis technique

Fluorine doped SnO₂ films have been successfully prepared at optimized substrate temperature of 723 K by spray pyrolysis technique. The XRD analysis confirmed that films deposited with F/Sn ratio of 0.05 showed a partial amorphous nature whereas films deposited with F/Sn = 0.10 exhibited tetragonal structure (2 0 0) as the preferred orientation and polycrystalline structure. The lattice constants were found to be a = 0.4750 and c = 0.3197 nm. The theoretically constructed XRD pattern for SnO₂ was used to compare with experimental pattern, the difference between them is discussed. By using SEM analysis, the surface morphology of the films was observed as an effect of the variation of F/Sn ratio. At low temperature, the mobility due to lattice, polar, impurity, grain boundary and neutral scattering was estimated for SnO₂ and the possible scattering mechanisms were assigned to SnO₂:F films using experimentally obtained electrical data. The Mott parameters were determined by applying variable range hopping (VRH) conduction mechanism for SnO₂:F films (F/Sn = 0.05) where band conduction mechanism shifted to VRH conduction at below about 250 K.     

The role of oxygen vacancy in fluorine-doped SnO2 films

The fluorine-doped tin oxide films (FTO) were prepared with SnCl₂ and SnCl₄ precursors using the spray pyrolysis method. The vibrational feature of oxygen vacancy in FTIR has been identified. The oxygen vacancy plays a role of donor in FTO films, although it becomes inconspicuous with an increase in fluorine concentration in the solution. The substitution of fluorine for oxygen has also been confirmed by FTIR spectrum, and it further indicates the production of fluorine doping is α-SnF₂. The reflectivity shows a close relation with the carrier concentration, suggested by the Drude theory. The discussion of scattering mechanism in FTO films suggests that impurity ions are the main scattering centers for free carriers.     

Effects of hydrogen plasma treatment on SnO2:F substrates for amorphous Si thin film solar cells

We investigated the effects of hydrogen plasma treatment on the physical and electrical properties of fluorine-doped tin oxide (FTO) films used for amorphous silicon (a-Si) thin film solar cells. A slight increase in carrier concentration by the hydrogen doping effect was observed for the FTO film exposed to the hydrogen plasma for 5 min. For further exposure to the plasma, the chemical reduction became prominent and resulted in deterioration of the electrical and optical properties of the film. XPS analysis revealed that the chemical reduction of SnO₂ to Sn metallic state occurs on the surface region. It was found that the defects formed by hydrogen plasma act as recombination centers at the interface between FTO electrode and p-layer of a-Si solar cells. This phenomenon resulted in the deterioration of the cell performance. The averaged conversion efficiency (6.82%) of the cells on pristine FTO hydrogen substrate was decreased to 5.81% for the cells on FTO treated for 5 min, which is mainly attributed to the decrease in short-circuit current density.     

Metal nanostructures with complex surface morphology: The case of supported lumpy Pd and Pt nanoparticles produced by laser processing of metal films

In this work we report on the formation of lumpy Pd and Pt nanoparticles on fluorine-doped tin oxide/glass (FTO/glass) substrate by a laser-based approach. In general, complex-surface morphology metal nanoparticles can be used in several technological applications exploiting the peculiarities of their physical properties as modulated by nanoscale morphology. For example plasmonic metal nanoparticles presenting a lumpy morphology (i.e. larger particles coated on the surface by smaller particles) can be used in plasmonic solar cell devices providing broadband scattering enhancement over the smooth nanoparticles leading, so, to the increase of the device efficiency. However, the use of plasmonic lumpy nanoparticles remains largely unexplored due to the lack of simply, versatile, low-cost and high-throughput methods for the controllable production of such nanostructures.Starting from these considerations, we report on the observation that nanoscale-thick Pd and Pt films (17.6 and 27.9 nm, 12.1 and 19.5 nm, respectively) deposited on FTO/glass surface irradiated by nanosecond pulsed laser at fluences E in the 0.5–1.5 J/cm² range, produce Pd and Pt lumpy nanoparticles on the FTO surface. In addition, using scanning electron microscopy analyses, we report on the observation that starting from each metal film of fixed thickness h, the fraction F of lumpy nanoparticles increases with the laser fluence E and saturates at the higher fluences. For each fixed fluence, F was found higher starting from the Pt films (at each starting film thickness h) with respect to the Pd films. For each fixed metal and fluence, F was found to be higher decreasing the starting thickness of the deposited film. To explain the formation of the lumpy Pd and Pt nanoparticles and the behavior of F as a function of E and h both for Pd and Pt, the thermodynamic behavior of the Pd and Pt films and nanoparticles due to the interaction with the nanosecond laser is discussed. In particular, the photothermal vaporization and Coulomb explosion processes of the Pd and Pt nanoparticles are invoked as possible mechanisms for the lumpy nanoparticles formation.     

Rational Design of Highly Efficient One-pot Synthesis of Ternary PtNiCo/FTO Nanocatalyst for Hydroquinone and Catechol Sensing

In this work, we present a simple and efficient method for preparation of widely dispersed PtNiCo nanocatalyst on FTO without the use of any heavy complex structure. The proposed nanocatalyst enhances the chemical interaction of PtNiCo/FTO and increases its catalytic activity, which was used for electrochemical sensing of catechol and hydroquinone. The surface morphology was characterized by TEM, HRTEM, and XRD. The size of the PtNiCo/FTO octahedrons nanocatalyst was about 0.35–4 nm. Gradual increase of concentration exhibited linearity in oxidation peak response up to 1100 μM with a low detection limit of 0.79 μM for HQ and 1.05 μM for CC. The sensitivity is 1035 μAmM⁻¹ cm⁻² for catechol and 1197 μAmM⁻¹ cm⁻² for hydroquinone. The prepared nanomaterial/sensor applied to real water samples with good reproducibility (98–99 %).     

基于FTO导电玻璃的碱性品红脱色研究

研究了基于FTO导电玻璃的碱性品红电化学脱色工艺,考察了环境酸度、电解质种类与浓度、电解电压、碱性品红初始浓度等因素对碱性品红脱色率的影响.结果表明,控制电解电压为9 V,对质量浓度为2.0 g/L氯化钠的碱性品红（0.03 g/L）溶液（pH 7.0）进行电化学降解20 min后,碱性品红的脱色率可达到92%.     

FTO薄膜制备技术研究进展

本文首先对FTO薄膜的特性和应用进行简明陈述,之后对薄膜的制备方法,包括溶胶-凝胶法、磁控溅射法、化学气相沉积法和喷雾热解法等现有制备技术及研究进展进行了全面的综述,最后对FTO薄膜的制备技术改进及FTO理论设计研究前景进行了展望.     

合成气直接转化制低碳烯烃催化剂设计及反应条件优化

采用水热法合成了相同粒径、不同硅铝比的ZSM-5分子筛,并通过浸渍法将Fe基（Fe-Cu-K）催化剂负载于ZSM-5上,系统考察了分子筛硅铝比变化对合成气制烯烃（FTO）反应的影响。结果表明,反应条件、分子筛酸性对CO转化率和低碳烯烃选择性有显著影响。当ZSM-5分子筛硅铝比为50时负载型催化剂有着最高的CO转化率（84.71%）和低碳烯烃选择性（32.08%）。H₂-TPR结果表明,硅铝比为50的Z50/FeCuK中Fe物相的还原度最高。原位漫反射红外光谱（DRIFTS）、热重差热分析（TG-DTA）、X射线粉末衍射（XRD）等结果表明,Z50/FeCuK催化剂表面吸附的碳酸盐和烃类吸附物种最多,且其反应后形成了较多的FeC_x晶相。最后对反应条件进行了优化,结果表明,温度为310 ℃,H₂/CO （volume ratio）=2和压力为1.0 MPa时FTO的催化性能最优。