H_2SO_4溶液中,RuO_2-TiO_2电极失效过程的俄歇电子能谱研究

对于Ti基RuO_2-TiO_2涂层形稳阳极(DSA,dimen.sionally stable anode)的失效原因,虽然进行过不少研究,但往往着重在电极电位发生突变,即电极失效后期;缺少对电极失效过程中电极性能的演变进行研究。我们在电化学方法研究基础上进一步采用俄歇电子能谱技术(AES),对寿命试验过程中不同电解时间的DSA电极的表面成份和纵向的元素分布进行了研究。     

Au单晶电极上H2O2的氧化反应研究

本文利用旋转圆盘电极系统研究了酸性介质中H₂O₂在Au(100)和Au(111)电极表面的电化学行为. 实验发现在Au电极上H₂O₂难以发生还原,但是当电位稍微正于H₂O₂氧化为O₂的平衡电势时即可发生氧化. 在Au(111)上H₂O₂氧化的起始电位比在Au(100)正0.1 V左右. Au(100)上的双桥位位点能增强反应中间体*OOH的吸附,可能是导致Au(100)上H₂O₂氧化反应超电势比Au(111)低的主要原因. 在较正电位区(E>1.2 V), 当电极表面被氧物种覆盖时,H₂O₂在两个电极上的氧化都会受到一定程度的抑制,这种影响在Au(111)上比Au(100)上更加明显,这与Au(111)上氧物种的生成与逆向还原可逆性差的趋势一致. 最后还将Au与Pt单晶电极上H₂O₂氧化的行为进行了对比分析.     

辣根过氧化物酶的电化学固定化及其对H2O2的生物电催化还原作用

利用电化学固定化方法制备了聚吡咯/辣根过氧化物酶(PP/HRP)膜电极,并研究了其电化学行为。在除氧的磷酸盐缓冲液介质中,PP/HRP电极加速H₂O₂的还原,归因于酶加成物的直接电子传递。探索HRP与电子传递体K₄Fe(CN)₆在聚吡咯(PP)膜中的同时固定化条件及其膜电极的电化学行为,实验证实,K₄Fe(CN)₆在酶膜中的存在使得H₂O₂的还原电位强烈正移,在-0.05V的工作电位下能对H₂O₂进行检测,相应的电极过程可用间接氧化还原催化机理解释。     

Ru(bpy)2(NCS)2染料敏化CdS/Zn2+TiO2复合半导体纳米多孔膜的光电化学

采用水热法合成了Zn²⁺离子掺杂的TiO₂纳米粒子[Zn²⁺掺杂量0.5%(物质的量的比)],并用光电化学方法研究了经Ru(bpy)₂(NCS)₂(bpy=2,2′bipyridine₄,4′dicarboxylicacid)分别敏化的掺杂Zn²⁺的TiO₂电极(简写为Zn²⁺-TiO₂)和CdS/Zn²⁺-TiO₂复合半导体纳米多孔膜电极的光电化学行为.实验证明Ru(bpy)₂(NCS)₂敏化CdS/Zn²⁺-TiO₂复合半导体纳米多孔膜电极比单独敏化Zn²⁺-TiO₂电极的光电转换效率高,且敏化Zn²⁺TiO₂电极和敏化CdS/Zn²⁺TiO₂复合半导体纳米多孔膜电极比Zn²⁺-TiO₂电极的光电流产生的起始波长都向长波方向移动.在360600nm范围内,Ru(bpy)₂(NCS)₂敏化CdS/Zn²⁺-TiO₂复合半导体纳米多孔膜电极光电转换效率最好.     

铜基电催化剂还原CO2

温室气体CO₂的大量排放给全球气候造成潜在威胁,电化学还原CO₂为有用的化工产品作为一种人为的碳循环的方式,拓展了新的利用CO₂的可能性,并且是一种很有前景的显著改善环境、促进可持续发展的方法。然而,在转化CO₂为有价值的产品过程中,最大的挑战是抑制析氢副反应的同时达不到高效率、高选择性。铜因其在电催化还原CO₂过程中优异的催化性能而得到广泛关注。本文重点介绍了近年来电催化还原CO₂的发展以及电化学转化CO₂的优缺点,介绍了CO₂RR的热力学与动力学研究并概述了Cu电极、Cu MOFs材料电极以及通过氧化、合金化、纳米化和表面修饰等方法修饰的铜电极的进展,但是电催化还原CO₂的反应机理尚不太确定。最后,讨论了未来铜基电极催化剂高效率地选择性转化CO₂会面临的挑战和可能研究的方向。     

电沉积Cu2xIn2-2xSe2薄膜的光电化学研究

用电沉积法制得Cu_2xIn_2-2xSe₂(铜铟硒)(0[1]并用EDAX对其组成进行分析。对薄膜电极的光电化学性能、光谱响应、能隙与x的依赖关系进行了研究。借助于现场微区扫描光电流谱观察了热处理、薄膜厚度、光极化对薄膜电极的光电性能影响。研究了Pb(NO₃)₂有效的浸渍对薄膜光电性能的影响。     

硬脂酸二茂铁酯L-B膜修饰SnO2电极的阻抗研究

测定了二茂铁衍生物——硬脂酸二茂铁酯L-B膜修饰SnO₂电极在Fe(CN)₆^3-/4-溶液中的阻抗性能,用单纯形法求出了等效电路中的元件参数值,计算了电极反应速度常数K_s。从分析SnO₂电极修饰不同层的硬脂酸二茂铁酯L-B膜的界面阻抗和电极反应的动力学性能,表明与在固相中研究的硬脂酸二茂铁酯L-B膜的阻抗性能明显不同,在Fe(CN)₆^3-/4-溶液中表现了电活性分子修饰电极的界面阻抗行为,进一步证实了修饰在SnO₂电极上的硬脂酸二茂铁酯L-B膜在Fe(CN)₆^3-/4-的氧化还原电极反应过程中,起电荷传递的中介作用。     

LiF-BaF2-LiCl熔盐体系中Li+的电化学行为

运用三电极在电化学工作站AUTOLAB以循环伏安法、计时电流法和计时电位法研究了LiF-BaF₂-LiCl熔盐体系中1203 K温度下锂在钨（W）电极上的电化学还原过程及其控制步骤. 结果表明,Li⁺在W电极上的还原过程是一步得电子的准可逆反应,析出电位在-1.0 V附近. 阴极过程受离子的扩散步骤控制,计算得出扩散系数为4.5 × 10^-6 cm²•s^-1.     

在TiO2纳米阵列上电沉积RuO2用于CO2电还原

传统上,RuO₂/TiO₂复合电极制备是通过在TiO₂/Ti基体上多次涂覆含Ru前驱体溶液和随后热分解（TD）来实现的. 为克服上述方法中Ru用量大和利用率低之不足, 本工作主要基于循环伏安法（CV）在TiO₂纳米管阵列（TNA）上电沉积RuO₂制备RuO₂^CV/TNA复合电极. SEM、GIXRD和CV结果表明, 电沉积的RuO₂为无定型结构, 所制备电极中的Ru用量约为传统的RuO₂^TD/TNA电极中Ru用量的1/30. 尽管两电极催化CO₂还原产物的法拉第效率接近, 但是RuO₂^CV/TNA电极比RuO₂^TD/TNA电极展示了更高的还原电流, 较正的初始还原电位和更好的稳定性. 与磷酸盐缓冲溶液中电还原CO₂相比,RuO₂^CV/TNA电极在0.1 mol•L^-1 KHCO₃中电还原CO₂除生成更高法拉第效率的甲酸根和甲烷外,还检测到CO的生成.     

3d过渡金属掺杂TiO2纳米晶膜电极的光电化学研究

应用原子力显微镜和X射线粉末法对3d过渡金属离子Cr(Ⅲ),Fe(Ⅲ),Mn(Ⅱ),Co(Ⅱ),Ni(Ⅱ),Cu(Ⅱ)和Zn(Ⅱ)掺杂TiO₂纳米晶粒(简写为m^3d-TiO₂)作了表征,并用光电化学方法研究了m^3d-TiO₂纳米结构多孔膜电极.实验结果表明,m^3d-TiO₂纳米粒子的颗粒较均匀,粒径约为15nm,其晶型为锐钛矿和板钛矿的混晶.在所研究的m^3d-TiO₂中,只有Zn²⁺-TiO₂电极的光电流大于未掺杂的TiO₂纳米结构多孔膜电极.3d金属离子的掺杂引起各电极的光电流信号在一定波长范围内出现p-n转型现象.     

PHOTOINACTIVATION OF CATALASE

Abstract— Inactivation of catalase with visible light (>400nm) has been studied in purified bovine liver catalase and in peroxisomal catalase in the mitochondrial fraction of rat liver. Light corresponding to that of maximal absorbance of the heme site (405 nm) was most effective in inactivation. Although photoinactivation is O₂ dependent, scavengers of OH radical, ¹O₂ and O⁻₂ did not protect against loss of activity in either system. Superoxide dismutase partially protected purified catalase added into the mitochondrial fraction system. However, complete protection of catalase was afforded by low concentrations of substrates such as formic acid or methanol which rapidly convert Compound I to Ferricatalase.     

六氯化铈三烷基鏻的合成

合成了三个新的(HPR₃)₂CeCl₆络合物,其中R=C₂H₅,C₃H₇,C₄H₉。络合物经元素分析,红外和紫外光谱鉴定。用热重分析法研究了这些络合物的热分解行为,结果表明,它们于分解温度时,都首先失去一个氯原子。     

SELECTIVE INACTIVATION OF MICROSOMAL DRUG METABOLIZING PROTEINS BY VISIBLE LIGHT

Abstract— Rat liver microsomes treated with heterochromatic visible light (λ > 400 nm) and O₂ showed a preferential inactivation of NADPH-cytochrome P₄₅₀ reductase and cytochrome P₄₅₀, proteins involved in drug metabolism. Cytochrome P₄₅₀ destruction correlates with lipid peroxidation; both are oxygen dependent and affected to the same extent by antioxidants and radical scavengers. Under anaerobic conditions. NADPH-cytochrome P₄₅₀ reductase is the only component which is inactivated; this is accompanied by FMN loss and activity can be restored by reconstitution.     

PHOTODYNAMIC INACTIVATION OF LYSOZYME BY EOSIN

Abstract— It has been demonstrated that singlet oxygen is the major oxidizing entity in the photo-dynamic inactivation of hen egg white lysozyme by eosin, using D₂O to enhance the solvent-induced decay lifetime, and azide ion as a specific scavenger. Two regimes of inactivation can be distinguished depending on whether the sensitizer is free or complexed to the enzyme. The kinetic analysis for free dye sensitization, based on photostationary measurements and inactivation quantum yields, indicates that at least 1 in 15 singlet oxygen interactions with lysozyme leads to loss of lytic activity. The direct attack of triplet eosin makes a lesser overall contribution in air-saturated solutions, where 1 in 4 reactions induces inactivation. Lysozyme binds 1 eosin molecule from pH 4 to 12, leading to almost total quenching of the tryptophyl residue fluorescence without inhibition of the enzymic activity. The inactivation quantum yields indicate that singlet oxygen generated from the bound dye is the inactivating agent, but the dominant attack takes place with the complexed fraction of lysozyme molecules. The tryptophyl residue loss is the same or smaller in changing from H₂O to D₂O despite the 5–10 times increase in quantum yield, indicating that singlet oxygen inactivates also by reacting with residues other than tryptophan. The photochemical and fluorescence results are consistent with the the identification of tryptophyl site 108 with the eosin binding site and a reaction target for singlet oxygen. In a re-examination of earlier work on eosin-sensitized photo-oxidation of I", it has been found that singlet oxygen is the oxidizing agent in aerobic solutions.     

DSA电极电催化性能研究及尚待深入探究的几个问题

钛基氧化物涂层电极(DSA^®)由于其对阳极析氯、阳极析氧、有机污染物电化学降解等具有优异的电催化活性而受到研究者的广泛关注,但DSA电极电催化现象背后的一些重要而基础性的问题仍未被人们完全认识。本文针对目前国内外有关DSA电极电催化研究领域中的几个研究热点、不足之处、以及尚待深入探究的问题,进行了简要介绍、分析和讨论。DSA电极的电催化活性主要是来自于其表面的金属氧化物涂层。本文强调对“氧化物涂层”自身固体物理-化学性能或过程的研究,有助于深入揭示钛基活性氧化物涂层电极电催化现象的微观作用机制和内在本质,并反过来指导人们更加理性地通过设计和优化DSA电极的制备方法和条件,调控表面氧化物涂层的化学组成与结构,进而达到增强钛基涂层电极电催化活性之目的。     

铱盐对AgCl(Br,Ⅰ)乳剂微晶体离子电导率的影响

本文用介电损耗法测定了(NH₄)₂IrCl₆和(NH₄)₃IrCl₆在不同加入量(10^-8～10^-3M/MAgX)时对物理成熟后的AgCl(Br、I)乳剂的离子电导的影响。随着铱盐加入量的不断增大,介电吸收峰f_max不断向低频方向偏移。当掺杂量达到10^-3M/MAgX时,吸收峰明显变宽。(NH₄)₂IrCl₆和(NH₄)₃IrCl₆的加入量相同时,这两种铱盐所导致的f_max的偏移也相近。 铱盐对于调变已经物理成熟的AgCl(Br,I)乳剂的离子电导率有很大作用。     

HEMATOPORPHYRIN DERIVATIVE-INDUCED PHOTODYNAMIC INHIBITION OF Na+/K+-ATPase IN L929 FIBROBLASTS, CHINESE HAMSTER OVARY CELLS AND T24 HUMAN BLADDER TRANSITIONAL CARCINOMA CELLS

The photodynamically induced inhibition of Na⁺/K⁺-ATPase with hematoporphyrin derivative as photosensitizer was studied in murine L929 fibroblasts, Chinese hamster ovary (CHO) cells and T24 human bladder transitional carcinoma cells. In T24 cells the inhibition of the enzyme activity appeared to be caused by ATP depletion rather than by direct damage from the enzyme itself. In L929 and CHO cells, on the other hand, the inhibition was caused by photodynamic damage from the enzyme molecule. For all three cell lines it was shown that a causal relationship between photodynamically induced reduction in Na⁺/K⁺-ATPase activity and the loss of clonogenicity is highly unlikely.     

端烯丙基聚硅氧烷的合成及其在乙烯聚合中的行为

通过与大分子单体的共聚合是合成接枝聚合物的一个重要方法。已有人合成了端苯乙烯和丙烯酸酯的聚硅氧烷大分子单体,本文报道对端烯丙基聚二甲基硅氧烷的合成以及添加聚硅氧烷对Ziegler-Natta型催化剂乙烯聚合行为的影响。     

QUANTITATION OF PHOTOSYSTEM II ACTIVITY IN SPINACH CHLOROPLASTS. EFFECT OF ARTIFICIAL QUINONE ACCEPTORS

Quantitation of photosystem II (PSII) activity in spinach chloroplasts is presented. Rates of PSII electron-transport were estimated from the concentration of PSII reaction-centers (Chl/PSII = 380:1 when measured spectrophotometrically in the ultraviolet [ΔA₃₂₀] and green [ΔA_540–550] regions of the spectrum) and from the rate of light utilization by PSII under limiting excitation conditions. Rates of PSII electron-transport were measured under the same light-limiting conditions using 2,5-dimethylbenzoquinone or 2,5-dichlorobenzoquinone as the PSII artificial electron acceptors. Evaluation is presented on the limitations imposed in the measurement of PSII electron flow to artificial quinones in chloroplasts. Limitations include the static quenching of excitation energy in the pigment bed by added quinones, the fraction of PSII centers (PSII_β) with low affinity to native and added quinones, and the loss of reducing equivalents to molecular oxygen. Such artifacts lowered the yield of steady-state electron transport in isolated chloroplasts and caused underestimation of PSII electron-transport capacity. The limitations described could explain the low PSII concentration estimates in higher plant chloroplasts (Chl/PSII = 600 ± 50) resulting from proton flash yield and/or oxygen flash-yield measurements. It is implied that quantitation of PSII by repetitive flash-yield methods requires assessment of the slow turnover of electrons by PSII_β and, in the presence of added quinones, assessment of the PSII quantum yield.     

SATURATION OF DNA REPAIR IN MAMMALIAN CELLS*

Abstract—Excision repair seems to reach a plateau in normal human cells at a 254 nm dose near 20J/m². We measured excision repair in normal human fibroblasts up to 80J/m². The four techniques used (unscheduled DNA synthesis, photolysis of BrdUrd incorporated during repair, loss of sites sensitive to a UV endonuclease from Micrococcus luteus , and loss of pyrimidine dimers from DNA) showed little difference between the two doses. Moreover, the loss of endonuclease sites in 24 h following two 20J/m² doses separated by 24 h was similar to the loss observed following one dose. Hence, we concluded that the observed plateau in excision repair is real and does not represent some inhibitory process at high doses but a true saturation of one of the, rate limiting steps in repair.