三维多孔Sn-Co合金负极制备及其电化学性能研究

采用化学镀方法制备三维多孔铜.以其作为集流体,借助电沉积制备三维多孔Sn-Co合金电极.X-射线衍射(XRD),扫描电镜(SEM)分析表明,以多孔铜为集流体制备的SnCo合金电极主要存在CoSn2相和纯Sn相,为三维多孔结构.充放电结果显示,三维结构SnCo合金电极比平面铜集流体上镀得的SnCo合金电极表现出更优越的充放电性能.前者的首次放电(嵌锂)容量为636.3mAh/g,充电(脱锂)容量为528.7mAh/g,首次库仑效率为83.1%,70周后容量为529.5mAh·g-1,保持率为82.6%.此外,还应用电化学阻抗初步研究了三维Sn-Co合金电极在充放电过程发生的嵌脱锂过程.     

氧化还原导电水凝胶制备及其在微生物燃料电池的应用

微生物细胞与微生物燃料电池阳极之间的电子传递效率是影响产电性能的关键因素.借助阳极修饰可以促进电子转移速率,提高电池的性能.本文合成了一种以聚4-乙烯基吡啶为骨架,中性红单体为氧化还原活性中心、具有良好导电性和生物兼容性的氧化还原水凝胶材料.其中通过共价键合固定氧化还原中介体,避免了对外界环境的二次污染.以该材料修饰碳纸作为阳极组装电池,实验表明经过修饰的生物阳极驯化周期缩短,阳极电势更接近NADH/NAD的平衡电位.该电池的功率密度较未修饰的电极的电池有明显的提高.     

有机体系中电合成纳米PbTiO3粉体及表征

The precursor PbTi(OCH₂CH₃)_6-y(acac)_y for the mixed oxide PbTiO₃was synthesized by electrochemical dissolution of Lead and Titanium with a 1∶2 electricity quality in ethanol and acetyl-acetone solution. Nano-sized PbTiO₃powder was prepared by drying and calcining the xerogel from a direct sol-gel hydrolyzation of the precursor solution under pH of 8.5. The FTIR, TG-DTA, XRD and TEM were employed to characterize the structure of the precursor and nano-sized PbTiO₃. The results showed that the optimized conditions for the preparation of nano-sized PbTiO₃ were the electrolysis of the Lead plate and Titanium plate at 50 ℃ and 40 ℃ respectively under 0.03mol·dm^-3Bu₄NBr solution. The nano-sized PbTiO₃prepared by electrolysis exhibited a dispersive structure with an average diameter of 10 to 15 nm.     

新型二氧化铅阳极电催化降解有机污染物的特性研究

通过XRD、SEM等表征,以酚类化合物为目标污染物,研究了经改性的新型含氟β-PbO2阳极电催化氧化污染物的特性.结果表明,该电极对酚类有机污染物的降解显示了良好的电催化活性、稳定性和抗腐蚀性,有较好的环保应用前景.进一步通过羟基自由基清除剂异丙醇加入前后降解效果的比较证实了本系统中有机污染物的降解主要基于羟基自由基的作用机理,是一种电化学高级氧化工艺.     

电化学合成系列锡配合物及纳米SnO2的制备

采用锡金属为"牺牲"阳极,首次在无隔膜电解槽中,电化学一步法制备了纳米SnO₂前驱体锡配合物Sn(OEt)₄, Sn(OBu)₄, Sn(OCH₂CH₂OCH₃)₄, Sn(OEt)₂(acac)₂, Sn(OBu)₂(acac)₂, Sn(OCH₂CH₂OCH₃)₂(acac)₂[acac为乙酰丙酮基],产物通过红外光谱(FT-IR)、拉曼光谱和核磁共振进行表征.同时采用含Sn(OR)₂(acac)₂>的电解液直接水解制备纳米SnO₂粉体,纳米SnO₂通过X射线粉末衍射(XRD)和透射电子显微镜(TEM)进行表征.实验表明,电解时防止阳极钝化,控制温度在40～60℃之间,采用有机胺溴化物为导电盐,可以提高电合成效率;电解合成Sn(OCH2CH₂OCH₃)₄, Sn(OEt)₂(acac)₂, Sn(OBu)₂(acac)₂, Sn(OCH₂CH₂OCH₃)₂(acac)₂的电流效率比Sn(OEt)₄, Sn(OBu)₄高,适宜作为溶胶-凝胶(Sol-gel)法制备纳米SnO₂的原料,制备得到的纳米SnO₂经600℃煅烧后呈球形单分散结构,晶型为四方锡石型,平均粒径在(10±0.4) nm左右.     

纳米NiAl_2O_4前驱体的电化学合成

在乙醇溶液中,按Ni/Al电量比为1∶3依次电解铝片和镍片,制得复合氧化物纳米粉体NiO Al2O3的前驱体NiAl2(OCH2CH3)(8-y)(acac)y[acac为乙酰丙酮基].产物通过红外光谱、X射线衍射、电子透射显微镜进行了表征,同时研究了镍电极在铝醇盐溶液中的电化学行为,讨论了影响电合成镍、铝醇盐配合物的关键因素.实验表明,电解温度控制在54～60℃、导电盐Bu4NBr浓度为0.040～0.045mol/L时,电流效率约为93%.水解后的干凝胶粒径在10nm左右,为纳米NiAl2O4粉体的制备创造了条件.     

采用高传导率银铜镍网格电极的柔性聚合物太阳能电池

采用一种新的阳极材料:银、铜、镍的复合金属网格阳极,利用旋涂法制成了活性层为P3HT (poly(3-hexylthiophene)):PCBM([6,6]-phenylC61-butyricacidmethylester)的柔性衬底聚合物太阳能电池.制备了5种不同结构的柔性聚合物太阳能电池器件,将采用新型阳极材料的柔性衬底聚合物太阳能电池与传统ITO(Indium tin oxide)阳极的柔性衬底聚合物太阳能电池进行对比,发现新型阳极材料所制成的器件性能得到大幅度的提高,其电池器件在50 mW/cm~2强度光照下,开路电压(V_(oc))为0.54 V,短路电流密度(J_(sc))为5.39 mA/cm~2,能量转换效率为2.060%.     

Oxygen-evolving SnO2-based Ceramic Anodes in Aluminium Electrolysis

This study deals with SnO₂-based ceramic anodes doped with Sb₂O₃ and CuO, aiming at contributing new data regarding their electrochemical behavior in cryolite melts. The performances of the anodes were evaluated by anodic polarization, cyclic voltammetry, and current efficiency and corrosion measurements. The investigation proves that the anodic process of SnO₂-based inert anodes occurs at a low overvoltage and the oxygen discharge takes place in one step with an exchange of two electrons. The current efficiency and corrosion were proved to be dependent on the electrolysis parameters and composition of electrolysis bath. For a long term electrolysis, the dissolution of the anode in the cryolite-alumina melt produced small aluminium contamination(ca. 0.2%, mass fraction).     

Preface to Special Issue on Electrochemical Energy Storage and Conversion

正Energy utilization includes two aspects of storage and conversion.Both the density of energy storage and the efficiency of energy conversion are particularly considered in the application of energy.It is well known that chemical energy can be easily stored in chemical substances with high-energy density such as those containing hydrogen and lithium.Meanwhile,     

三维花状Fe_2(MoO_4)_3微米球的水热制备及电化学性能

以Fe Cl3·7H2O和Na2Mo O4为原料,采用水热合成法制备三维花状Fe2(Mo O4)3微米球。探讨不同合成温度对样品形貌的影响,利用XRD、SEM和EDS等分析技术对样品的结构、形貌进行了表征,对该材料的电化学性能进行了测试。结果表明:Fe2(Mo O4)3微米球是由二维纳米片自组装而成的花状结构,合成温度为160℃时,制备的样品具有良好的电化学性能,当电流密度为100 m A·g-1,首次放电比容量为1 431 m Ah·g-1;并具有较好的循环性能和倍率性能。并对160℃合成样品表现较好电化学性能的原因进行了探讨。