镍铂修饰n型硅电极光电解析氧

本文以n/n^+-Si半导体为基底, 通过碱溶液刻蚀处理和Ni/Pt双层金属膜表面修饰后作为光阳极, 用于1.0mol·dm^-^3KOH溶液中光助电解水析氧。在恒电势1.0V(相对HgO/Hg电极)和90mW·cm^-^2光照射下, 最佳电极的析氧电流达到65.2mA·cm^-^2, 稳定性实验表明, 连续光照不超过200小时, 光电极具有良好的抗腐蚀性。对电极表面进行了X-光电子能谱(ESCA)分析。     

CuInSe2/氰桥混配物复合修饰光电极的制备及其光电性质

利用电沉积法在氰桥混配物预修饰的玻璃碳电极上再沉积CuInSe2半导体材料,制备了一种复合型修饰光电极(Eu-Fe-Mo/CuInSe2)。以含Cu2+、In3+、SeO23-及柠檬酸钠的酸性水溶液为电镀液,通过优化寻找到电镀液中最佳的Cu∶In∶Se料液比例,用恒电位电沉积法可以制备出具有良好光电效应的复合型修饰光电极。用SEM、EDS技术对复合修饰光电极的表面形貌及其修饰材料的元素组成进行了表征;以60 W的普通日光型白炽灯为光源,采用开路电压和计时安培法研究了该复合修饰光电极的光电性质。测得该光电极的响应光电压大于30 mV,响应光电流密度大于8.9×10-6A/cm2。实验结果表明,该复合修饰光电极呈现典型p型半导体的光电性质。     

外延p-Si中的高-低结对光电化学转换效率的影响

本文采用p⁺/p-Si作为光阴极进行了光电化学电池和光助析氢电池的研究,光转换效率分别达到了7.4%(V^2+/3+电对)和7.8%(Co—W修饰),并讨论了导致高效率的原因,强调了高-低结对于改善半导体光电极性能的重要性。     

多晶富镉Hg_(1-x)Cd_xTe的电沉积及Hg_(0.09)Cd_(0.91)Te薄膜的光电化学行为

本文研究了在酸性CdSO_4+HTeO_2~+6HgCl_2 电解液中多晶富镉Hg_(1-x),Cd_(?),Te(x>0.5)的电沉积过程,实现了三种离子在同一电位下共沉积的技术。对在钛基底上沉积出的薄膜进行XRD,SEM和EDAX分析,结果表明薄膜为闪锌矿型的多晶结构,分布均匀连续。考察了(1—x)=0.09时多晶薄膜在多硫氧化还原电对液中的光电化学行为,光强为100mW/cm~2时,短路光电流I_(sc)=1.88mA/cm~2,开路光电压V_(oc)=0.25V,填充因子F·F=0.22。由光电化学光谱所确定出的禁带宽度E_g=1.26eV,Mott-schottky曲线给出了电极的平带电位φfb为—1.26V(vs.SCE),从而得到开路光电压V_(oc)可能达到的最大值为0.49V。因此,多晶富镉Hg_(1-x)Cd_xTe薄膜是一种很有潜力的光活性电极材料。     

TiO2纳米微球的制备及在染料敏化太阳能电池中的应用

以四氯化钛、盐酸为原料,制备出花状TiO₂纳米微球,利用扫描电子显微镜（SEM）、X射线衍射（XRD）等测试方法,对样品的结构和形貌进行了表征。为了提高TiO₂微球电池的光电性能,利用TiO₂微球作为反射层构造了双层结构的薄膜电极,结果表明,双层结构染料敏化太阳能电池在100 mW·cm^-2（1.5 G）光照条件下,短路光电流J_sc为17.64 mA·cm^-2,开路光电压Voc为0.74 V,填充因子FF为0.63和光电转化效率η为8.33%。相比TiO₂微球制备的太阳能电池,双层结构染料敏化太阳能电池光电转化效率提高至5.3倍。最后对电极中染料的吸附量、电极的光散射性能和电池的电化学阻抗做了进一步研究和分析,研究表明,双层结构电池增强光的捕获能力,从而提高光伏性能。     

TiO2纳米微球的制备及在染料敏化太阳能电池中的应用

以四氯化钛、盐酸为原料,制备出花状TiO_2纳米微球,利用扫描电子显微镜(SEM)、X射线衍射(XRD)等测试方法,对样品的结构和形貌进行了表征。为了提高TiO_2微球电池的光电性能,利用TiO_2微球作为反射层构造了双层结构的薄膜电极,结果表明,双层结构染料敏化太阳能电池在100 m W·cm-2(1.5 G)光照条件下,短路光电流Jsc=17.64 m A·cm-2,开路光电压Voc=0.74 V,填充因子FF=0.63和光电转化效率η=8.33%。相比TiO_2微球制备的太阳能电池,双层结构染料敏化太阳能电池光电转化效率提高至5.3倍。最后对电极中染料的吸附量、电极的光散射性能和电池的电化学阻抗做了进一步研究和分析,研究表明,双层结构电池增强光的捕获能力,从而提高光伏性能。     

过渡金属电催化剂在硅基光阳极分解水产氧中的作用

光电化学分解水可将太阳能转换为绿色的氢能,为目前的能源危机和环境问题提供了一种理想的解决方案.在分解水反应中,涉及四空穴过程的产氧半反应是制约性能的关键步骤,往往需要在半导体表面沉积电催化剂以加速产氧反应动力学.因此,全面理解电催化剂在光电化学分解水体系中的作用至关重要.在目前的产氧电催化剂中,过渡金属羟基氧化物电催化剂(MOOH,M=Fe,Co,Ni)因其环保、廉价、高效以及稳定的特性,已被广泛用于半导体光阳极分解水器件中.而且,MOOH可用简单的电沉积方法沉积在光电极表面,易于大面积制备.然而,电沉积法制备的MOOH具有复杂的结构,对其作用机制的全面理解更加困难.因此,本文以电沉积MOOH修饰的硅基光阳极(n⁺p-Si/SiO_x/Fe/FeOx/MOOH)作为模型,研究了不同电催化剂对硅光阳极光电化学产氧性能的影响.实验发现电催化剂的界面优化在电催化剂修饰的光电极中发挥着重要作用,这是因为优化的界面可以提升界面电荷传输,提供更多的催化反应活性位点以及更高的本征催化活性,从而更有利于光解水性能的提升.该项研究揭示了电催化剂在光解水器件中的作用,并为今后高效光解水器件的设计提供了一定指导.首先在多晶n⁺p-Si基底上热蒸镀了一层30 nm的金属Fe膜,并通过电化学活化将Fe膜表面转换为FeOx得到Fe/FeOx(记作aFe)界面层,然后利用电沉积方法制备MOOH表面修饰层,最终得到n⁺p-Si/SiO_x/aFe:MOOH光阳极.X射线光电子能谱、拉曼光谱以及扫描电子显微镜表面元素成像的表征结果均证实电极表面由于界面层金属Fe元素的掺杂而形成了Fe1-xNixOOH.在模拟太阳光下用于光解水产氧时,n⁺p-Si/SiO_x/aFe:NiOOH电极的起始电位为~1.01 VRHE(相对于可逆氢电极的电势),在1.23 VRHE下的光电流为38.82 mA cm^-2,显著优于n⁺p-Si/SiO_x/aFe、n⁺p-Si/SiO_x/aFe:FeOOH以及n⁺p-Si/SiO_x/aFe:CoOOH三个对比样品,且其稳定性达到75 h.另外,我们发现n⁺p-Si/SiO_x/aFe:MOOH电极的光电化学产氧性能均显著高于n⁺p-Si/SiO_x/aFe电极,且p++-Si/SiO_x/aFe:MOOH的电催化产氧性能也高于p++-Si/SiO_x/MOOH,不仅证明了aFe界面层对Si与MOOH层之间的界面接触作用的有效调控,而且表明双电催化剂体系(aFe:MOOH)的电催化产氧活性高于单电催化剂(MOOH).热力学分析表明,n⁺p-Si/SiO_x/aFe:MOOH光阳极的光电压大小与其光解水产氧性能并不一致,从而排除了热力学因素对性能的关键影响.进一步从塔菲尔斜率、电化学活性表面积和电化学阻抗谱对各电极的动力学进行了分析,证明了动力学因素在上述光阳极产氧性能中的主导作用.同时发现,由于aFe:NiOOH双电催化剂具有更高的本征电催化产氧性能,提供了更多的表面活性位点以及更有效地促进了光生载流子的传输,对动力学的提升效果更显著,从而使n⁺p-Si/SiO_x/aFe:NiOOH光阳极表现出最高的光解水产氧性能.     

光电化学水分解中铁酸盐光阴极的制备与改性

由n型半导体光阳极和p型半导体光阴极组成的无偏压光电化学电池通过太阳能可以将水直接转化为高能量密度的氢气,为解决太阳能利用过程中存在的间歇性和储存问题提供了一种潜在的经济有效的解决途径。金属氧化物具有低成本和易制备等优势,相比于发展较成熟的n型光阳极金属氧化物材料,传统的p型光阴极金属氧化物材料由于金属离子易受到光电腐蚀的影响,光电极寿命的提升是个很大的挑战。作为新型的金属氧化物光阴极材料,铁酸盐具有合适的带隙、较好的光稳定性、较正的起始电位以及较低的制备成本,正在成为光电化学电池实际应用中的有力竞争者。本文阐述了光电化学水分解的基本原理与提升光电极性能的一般方法,总结了近年来颇受关注的代表性铁酸盐光阴极材料CuFeO₂、CaFeO₄与LaFeO₃在制备方法、元素掺杂以及表面修饰等方面取得的重要进展,并对铁酸盐光阴极的未来发展趋势做了展望。     

N3敏化Ho3+离子修饰TiO2纳米晶电极的光电化学性质

研究了Ho3+离子表面修饰对TiO2纳米晶电极光电性能的影响. TiO2表面氧化钬的存在一方面降低了染料和TiO2之间的电子注入速率, 而另一方面它也能够抑制电荷复合. 结果表明, 在TiO2纳米晶薄膜表面修饰一定厚度的Ho3+离子层, 在电极表面就形成了一个势垒, 能够有效抑制电极表面的电荷复合, 从而提高了染料敏化太阳能电池的光电压和光电转化效率. 在93.1 mW·cm-2白光照射下, TiO2/Ho-0.1 和TiO2/Ho-0.2(0.1 和0.2分别是修饰TiO2电极的Ho3+溶液的浓度, 单位是mol·L-1)两个电极的光电转化效率分别达到8.3%和7.6%, 与TiO2电极(7.2%)比较, 分别增大了15%和5%.     

Ce^4^+/Ce^3^+-V^2^+/V^3^+氧化还原流动电池的可行性研究2: 旋转圆盘(RDE) 与旋转环盘(RRDE)法对Ce^4^+/Ce^3^+氧化还原体系的研究

用RDE与RRDE法研究了Ce^4^+/Ce^3^+-V^2^+/V^3^+氧化还原流动电池中Ce^4^+/Ce^3^+体系的电化学动力学参数,以说明组成该新型氧化流动电池的可能性。用RDE法得出在铂电极表面与玻碳电极上均会生成一层氧化膜,对Ce^3^+的氧化的反应产生阻碍作用。但在铂上的氧化膜对Ce^4^+的还原反应却有催化作用。用RRDE法得出Ce^3^+在玻碳电极上的氧化与析氧之间存在着竟争,为得到高的Ce^3^+氧化效率,应控制氧化电流在2～8mA.cm^-^2之间。     

High performance solution-processed indium oxide thin-film transistors

In2O3 thin-film transistors (TFTs) were fabricated on various dielectrics [SiO2, self-assembled nanodielectrics (SANDs)] by spin-coating In2O3 film precursor solutions consisting of ethanolamine (EAA) and InCl3 in methoxyethanol. Optimized film microstructures are characterized by the high-mobility In2O3 00 L orientation and are obtained only within a well-defined range of base: In3+ molar ratios. Electron mobilities as high as approximately 44 cm2 V(-1) s(-1) are measured for n+-Si/SAND/In2O3/Au devices using an EAA/In3+ molar ratio = 10. This result combined with Ion/Ioff ratios of approximately 10(6) and <5 V operating voltages is encouraging for high-speed applications.In2O3 thin-film transistors (TFTs) were fabricated on various dielectrics [SiO2, self-assembled nanodielectrics (SANDs)] by spin-coating In2O3 film precursor solutions consisting of ethanolamine (EAA) and InCl3 in methoxyethanol. Optimized film microstructures are characterized by the high-mobility In2O3 00 L orientation and are obtained only within a well-defined range of base: In3+ molar ratios. Electron mobilities as high as ~44 cm2 V(-1) s(-1) are measured for n+-Si/SAND/In2O3/Au devices using an EAA/In3+ molar ratio = 10. This result combined with Ion/Ioff ratios of approximately 10(6) and <5 V operating voltages is encouraging for high-speed applications.     

A novel photoelectrochemical hydrogen peroxide sensor based on nickel(II)-potassium hexacyanoferrate-graphene hybrid materials modified n-silicon electrode

A platinum (Pt) film coated n-silicon (Pt/n-n⁺-Si) was modified with nickel(II)-potassium hexacyanoferrate (NiHCF)-graphene sheets (GS) hybrid and used as a photo-electrochemical (PEC) sensor for non-enzyme hydrogen peroxide (H₂O₂) detection. A NiHCF film was deposited on the surface of GS/Pt/n-n⁺-Si electrode by chemical method. The structure and composition of the NiHCF film was characterized by X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS). PEC behavior of the NiHCF-GS/Pt/n-n⁺-Si electrode was investigated using cyclic voltammetry (CV) under illumination. The modified electrode has been used as PEC sensor for H₂O₂ detection with a linear range of 2.0 × 10^?6–2.9 × 10^?3 M and a detection limit of 1.0 × 10^?6 M at a signal-to-noise ratio of 3 in a two-electrode cell with a Pt plate as counter electrode. The characteristics of GS layer have been discussed in both the improvement of sensibility and selectivity.     

Reversible redox reaction and water configuration on a positively charged platinum surface: first principles molecular dynamics simulation

The water dissociation reaction and water molecule configuration on a positively charged platinum (111) surface were investigated by means of first principles molecular dynamics under periodic boundary conditions. Water molecules on the Pt surface were mostly in the O-down orientation but some H-down structures were also found. OH(-) ion, generated by removing H from H(2)O in the bulk region, moved to the Pt surface, on which a positive charge is induced, by a Grotthuss-like proton-relay mechanism and adsorbed on it as OH(Pt). Hydrogen atom exchange between OH(Pt) and a near-by water molecule frequently occurred on the Pt surface and had a low activation energy of the same order as room temperature energy. When a positive charge (7 μC cm(-2)) was added to the Pt surface, H(3)O(+) and OH(Pt) were generated from 2H(2)O on the Pt. This may be coupled with an electron transfer to the Pt electrode [2H(2)O → H(3)O(+) + OH(Pt) + e(-)]. The opposite reaction was also observed on the same charged surface during a simulation of duration about 10 ps; it is a reversible redox reaction. When further positive charge (14 μC cm(-2)) was added, the reaction shifted to the right hand side completely. Thus, this one-electron transfer reaction, which is a part of the oxygen electrode reaction in fuel cells and water electrolysis, was confirmed to be a low activation energy process.     

Using layer-by-layer assembly of polyaniline fibers in the fast preparation of high performance fuel cell nanostructured membrane electrodes

Membrane electrode assemblies (MEA) for fuel cells require optimization of their nanoscale organization to reach performance parameters, which include enhanced power density, increased catalyst utilization and reduced cost. We applied sprayed layer-by-layer assembly to produce a high activity MEA for H(2)/O(2) fuel cells from polyaniline fibers (PANI-F). This technique produces "fast-prepared" membranes with nanoscale structure, which allows to adequately address specific tuning of their porosity, platinum loading, electronic conductivity, and proton conductivity. Pt nanoparticles were attached to the PANI-F in a reaction of selective heterogeneous nucleation. After functionalization, Pt/PANI-F were assembled with Nafion. Microscopic investigation revealed that functionalized polyaniline fibers formed a highly porous yet tight network of interpenetrating conductors connected to the catalytic Pt particles. The Pt/PANI-F LBL ultrathin MEA demonstrated a power densitiy of 63 mW cm(-2) and yielded a Pt utilization of 437.5 W g(-1) Pt which is comparable to the traditional fuel cell using carbon black as Pt support. Moreover, the amount of Pt used in this work is almost 2 times lower than for usual carbon-supported Pt catalysts.     

直接乙醇燃料电池初探

采用商品化的PtRu/C和Pt/C分别作乙醇阳电极和氧气阴电极的催化剂 ,Nafion 115膜作固体电解质 ,组装成面积为 9cm2 的单池 .考察了电池温度、氧气压力、乙醇浓度及流量等对电池性能的影响 .实验结果表明在电池温度为 85℃ ,乙醇浓度为 1.0mol/L ,流量为 0 .5mL/min ,氧气压力为 0 .5MPa ,流量为 6 8mL/min条件下 ,电池开路电压为 0 .6 0 8V ,电流密度 5 0mA/cm2 时的放电端电压为 0 .32 9V ,电池最大功率密度为 19.2 5mW /cm2     

MULTIPLE MODALITY TREATMENT OF CARCINOMA CELLS WITH Pt(Rh-123)2 PLUS X-RAY PLUS LIGHT

A complex of platinum tetrachloride with two molecules of rhodamine-123 (Rh-123), Pt(Rh-123)2, has been reported to act as hypoxic cell radiosensitizer of carcinoma cells in vitro and in vivo. In the present paper we report that Pt(Rh-123)2 photosensitizes human mammary carcinoma (MCF-7) cells and cis-platinum resistant human mammary carcinoma (MCF-7/CP) cells to 400-800 nm light in vitro. The efficiency of photosensitization by Pt(Rh-123)2 was 10 times greater than for Rh-123. Combination therapy using Pt(Rh-123)2 plus x-ray plus light was also much more effective compared to the combination therapy using Rh-123 plus x-ray plus light. After 15 microM of Rh-123 plus x-ray (0-8 Gy) plus light (5 J/cm2) treatment, cell survival curve was parallel to the x-ray cell survival curve with an initial decrease in the surviving fraction corresponding to the drug plus light mediated killing. Cell killing caused by Rh-123 (15 microM) plus x-ray (0-8 Gy) plus light (5 J/cm2) was additive as determined by the product of the surviving fraction after Rh-123 plus light and x-ray. In contrast, for 15 microM of Pt(Rh-123)2 plus x-ray (8 Gy) plus light (5 J/cm2) treatment, whereas additive killing predicts a survival fraction of approximately 0.024, in reality, the combination therapy caused the survival fraction to decrease to 0.0012, implying that the cell killing was enhanced by a factor of 20. Using Pt(Rh-123)2 plus x-ray plus light, supra-additive cell killing was also observed under hypoxic conditions, although compared to normally oxygenated conditions the degree of cytotoxicity was significantly reduced.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nickel oxide hydroxide/platinum double layers modified n-silicon electrode for hydrogen peroxide determination

A novel photo-electrochemical and non-enzymatic hydrogen peroxide (H₂O₂) sensor was fabricated by electrochemically cathodic plating nickel hydroxide (Ni(OH)₂) on platinum films coated n-silicon (Pt/n-n⁺-Si electrode). Nickel oxide hydroxide (Ni(OH)₂-NiOOH) films on the Pt/n-n⁺-Si electrode were formed by cyclic voltammetry in 0.2 M KOH solution. The morphology and composition of Ni(OH)₂-NiOOH film were characterized via scanning electron microscopy (SEM) and X-ray photoelectron spectroscopy (XPS), respectively. A two-electrode cell based on Ni(OH)₂-NiOOH/Pt/n-n⁺-Si electrode and a platinum counter has been used for determination of H₂O₂ in the absence of reference electrode by photocurrent measurement at a zero bias. In these conditions a sensitivity of 96.9 μA mM^?1 cm^?2 and a linear response range from 0.02 up to 0.16 mM with a determination limit (S/N?=?3) of 5.4 μM were achieved in KOH solution at pH 13.3. In addition, the electrode also exhibited superior stability, anti-interference and selectivity.     

Photoelectrochemical Character of TiO2 Nanocrystalline Electrodes Sensitized by Aluminum Phthalocyanines Modified with Sulfonate Groups

IntroductionIn recent years, dye-sensitized solar cells(DSSCs) have attracted more and more attention be-cause of their low cost and simple fabrication[1—3].They are made of four parts: a photo-electrode, a dyesensitizer, an electrolyte and a counter-ele…     

Specific adsorption of histidine-tagged proteins on silica surfaces modified with Ni2+/NTA-derivatized poly(ethylene glycol)

Silica surfaces modified with nitrilotriacetic acid (NTA)-polyethylene glycol (PEG) derivatives were used to immobilize hexahistidine-tagged green fluorescent protein (His6-GFP), biotin/streptavidin-AlexaFluor555 (His6-biotin/SA-AF), and gramicidin A-containing vesicles (His6-gA). Three types of surface-reactive PEG derivatives-NTA-PEG3400-Si(OMe)3, NTA-PEG3400-vinylsulfone, and mPEG5000-Si(OMe)3 (control)-were grafted onto silica and tested for their ability to capture His6-tag species via His6/Ni2+/NTA chelation. The composition and thicknesses of the PEG-modified surfaces were characterized using X-ray photoelectron spectroscopy, contact angle, and ellipsometry. Protein capture efficiencies of the NTA-PEG-grafted surfaces were evaluated by measuring fluorescence intensities of these surfaces after exposure to His6-tag species. XPS and ellipsometry data indicate that surface adsorption occurs via specific interactions between the His6-tag and the Ni2+/NTA-PEG-grafted surface. Protein immobilization was most effective for NTA-PEG3400-Si(OMe)3-modified surfaces, with maximal areal densities achieved at 45 pmol/cm2 for His6-GFP and 95 fmol/cm2 for His6-biotin/SA-AF. Lipid vesicles containing His6-gA in a 1:375 gA/lipid ratio could also be immobilized on Ni2+/NTA-PEG3400-Si(OMe)3-modified surfaces at 0.5 mM total lipid. Our results suggest that NTA-PEG-Si(OMe)3 conjugates may be useful tools for immobilizing His6-tag proteins on solid surfaces to produce protein-functionalized surfaces.