Ni-Fe/Ti和Ni-Fe-S/Ti的制备及其电催化水分解性能

以钛网为基底,采用电沉积法制备了Ni-Fe/Ti析氧电极,然后将得到的Ni-Fe/Ti电极通过固相硫化制备了Ni-Fe-S/Ti析氢电极. 分别考察了电沉积液中Ni ²⁺/Fe ³⁺离子摩尔浓度比和硫脲加入量对Ni-Fe/Ti和Ni-Fe-S/Ti结构和电化学性能的影响. 结果表明,随着电沉积液中Ni ²⁺含量的增加,Ni-Fe/Ti电极析氧性能先增强后减弱,Ni9Fe1/Ti电极具有最好的析氧性能;随着硫脲加入量的增加,Ni-Fe-S/Ti电极析氢性能呈现先增强后减弱的趋势,Ni9Fe1S0.25/Ti电极具有最好的析氢性能. 在50 mA·cm ^-2下,Ni9Fe1/Ti电极的析氧过电位为280 mV,Ni9Fe1S0.25/Ti电极的析氢过电位为269 mV,且均具有很好的稳定性. 将Ni9Fe1/Ti与Ni9Fe1S0.25/Ti分别作为阳极和阴极进行电催化全水分解,电流密度达到50 mA·cm ^-2所需电势仅1.69 V,表现出很好的全水解催化性能.     

Ni/Ag2O/RuO2-Pt阴极制备与析氢性能

以三氯化钌和氯铂酸为源物质,用溶胶凝胶法制备Ni/Ag2O/RuO2-Pt复合阴极,研究了不同涂覆液AgNO3浓度和热处理温度对该阴极析氢性能的影响.采用SEM-EDS、XRD和XPS观察阴极的表面形貌、表征其组分,结果表明,Ni/Ag2O/RuO2-Pt复合阴极表面致密,粗糙度大且裂纹少.电化学测量表明,在11 mol.L-1NaOH(90℃)溶液、0.3 A.cm-2电流密度下,Ni/Ag2O/RuO2-Pt复合阴极的析氢电位比纯Ni电极正移484 mV;交换电流密度是纯Ni电极的10倍.该阴极制备工艺简单,析氢活性高,有望降低氯碱工业的能耗.     

含稀土的镍基合金的析氢电催化行为

用电沉积方法制备的Ni-Ce-P和Ni-La-P合金作阴极测得析氢阴极极化曲线,结果表明,合金电极上析氢速率比Ni电极上约大10倍,析氢电热政移＞200mV,显示出含稀土的镍基合金具有较高的析氢催化活性,根据XPS谱图讨论了析氢的电催化机制。     

电沉积纳米镍合金在海水溶液中的析氢性能

采用电沉积法获得Ni、Ni-Fe和Ni-Fe-C合金镀层电极, 在90 °C模拟海水(0.5 mol·L-1 NaCl, pH=12)的稳态极化曲线表明Ni-Fe-C合金电极具有最好的析氢催化性能. 通过扫描电子显微镜(SEM)观察电极表面形貌、X射线衍射(XRD)与透射电子显微镜(HRTEM)分析合金的晶体结构, 发现电极材料的晶粒尺寸影响析氢催化性能, 晶粒尺寸越小析氢催化活性越好. 用电化学阻抗方法(EIS)研究电极析氢催化性能的本质原因, 结果表明电极表面活性点数目和电极的本质电催化活性对合金电极析氢催化活性有重要的影响.     

多孔Ni、Ni-Mo合金及其氧化物的制备与析氢性能

采用快速凝固结合脱合金化的方法制备了纳米多孔Ni、Ni-Mo合金及其氧化物电极材料,通过XRD、SEM、TEM、BET等对电极的物相、形貌结构、孔径分布进行表征,通过线性扫描伏安法、Tafel斜率和计时电位等方法测试多孔电极的电催化析氢性能。结果显示,制备的电极材料在10 mA·cm-2电流密度下Ni-Mo合金析氢活性最强,析氢过程由Volmer-Heyrovsky步骤控制,其表观交换电流密度为0.25 mA·cm-2,经10 000 s恒电流密度(100 mA·cm-2)电解后析氢过电位(η)仅增加39 mV,表现出优良的析氢稳定性。Ni-Mo合金电极比表面积的提高和本征催化活性的改善使其获得了更低的析氢过电位。     

Ni-Co-LaNi5复合电极材料在碱性介质中的电催化析氢性能

电催化析氢反应是电能向化学能转化的一个有效途径,是电化学科学中一个非常值得深入研究的课题。阴极析氢超电势的降低,是提高析氢活性,降低电解能耗的关键。为了提高电极的电催化活性,一是可通过提高电极表面的真实表面积,来降低电解过程中电极表面的真实电流密度,达到降低析氢超电势的目的;另一发展方向是提高电极材料本身的电化学活性,即寻找高催化活性的新型析氢材料犤1犦。由于过渡金属具有特殊的d电于结构,是目前公认的电化学活性最好的电极材料,而在过渡金属中,Ni及Ni合金将是研究的主要方向,其中多元合金复合材料将成为该技术发展…     

电沉积纳米镍合金在模拟海水溶液中的析氢性能

采用电沉积法获得Ni、Ni-Fe和Ni-Fe-C合金镀层电极,在90℃模拟海水(0.5mol·L-1NaCl,pH=12)的稳态极化曲线表明Ni-Fe-C合金电极具有最好的析氢催化性能.通过扫描电子显微镜(SEM)观察电极表面形貌、X射线衍射(XRD)与高分辨透射电子显微镜(HRTEM)分析合金的成分和晶体结构,发现电极材料的晶粒尺寸影响析氢催化性能,晶粒尺寸越小析氢催化活性越好.用电化学阻抗方法(EIS)研究电极析氢催化性能的本质原因,结果表明电极表面活性点数目和电极的本质电催化活性对合金电极析氢催化活性有重要的影响.     

纳米多孔Ni、Ni3S2/Ni复合电极的制备及其电催化析氢性能

采用脱合金化和水热合成的方法制备纳米多孔Ni和纳米多孔Ni₃S₂/Ni复合电极。通过N₂吸附-脱附测试、XRD、SEM、TEM等方法表征电极的孔径分布、物相和微观结构。在1 mol·L^-1的NaOH溶液中,运用线性扫描伏安（LSV）曲线、交流阻抗（EIS）谱图、恒电流电解法等测试电极的电催化析氢性能。结果表明：在电流密度为50 mA·cm^-2时,与纳米多孔Ni相比,Ni₃S₂/Ni合金具有更低的析氢过电位以及更高的析氢活性,同时纳米多孔Ni₃S₂/Ni复合电极具有更低表观活化能和电子转移阻抗,进一步明确了过渡金属硫化物对电催化析氢性能的特殊贡献。     

Ni/NiCo2O4复合电极的制备及其在碱性介质中的析氧性能

采用共沉淀法制备尖晶石型复合氧化物 NiCo2O4, 然后将其加入瓦特镀镍液中, 复合电沉积了 Ni/NiCo2O4复合镀层. 通过改变镀液pH值、阴极电流密度jk等条件, 探索复合电沉积的最佳工艺条件. 运用扫描电子显微镜(SEM)、能谱分析(EDS)和X射线衍射(XRD)表征了复合镀层的表面形貌、颗粒含量和结构. 结果表明: 在镀液pH=6.2和jk=100 mA·cm-2的条件下所得Ni/NiCo2O4复合镀层中, NiCo2O4的含量达到最高(30.6%,w). 在5 mo·lL-1的KOH溶液中, 采用循环伏安、稳态极化和电化学阻抗法研究了电极的电催化析氧性能. 与镍电极对比, Ni/NiCo2O4复合电极的电催化析氧性能更高, 表观活化自由能降低了53.2 kJ·mol-1, 其析氧反应的表观交换电流密度是镍电极的7倍. 电化学阻抗谱分析表明, Ni/NiCo2O4复合电极在碱性溶液中析氧反应由电化学步骤和扩散步骤联合控制. 恒电位长时间电解析氧实验表明, 该Ni/NiCo2O4复合电极在碱性溶液中的析氧具有高的稳定性.     

纳米多孔Ni、Ni3S2/Ni复合电极的制备及其电催化析氢性能

采用脱合金化和水热合成的方法制备纳米多孔Ni和纳米多孔Ni₃S₂/Ni复合电极。通过N2吸附-脱附测试、XRD、SEM、TEM等方法表征电极的孔径分布、物相和微观结构。在1 mol·L^-1的NaOH溶液中,运用线性扫描伏安(LSV)曲线、交流阻抗(EIS)谱图、恒电流电解法等测试电极的电催化析氢性能。结果表明:在电流密度为50 mA·cm^-2时,与纳米多孔Ni相比,Ni₃S₂/Ni合金具有更低的析氢过电位以及更高的析氢活性,同时纳米多孔Ni₃S₂/Ni复合电极具有更低表观活化能和电子转移阻抗,进一步明确了过渡金属硫化物对电催化析氢性能的特殊贡献。     

电沉积Ni/LaNiO3复合电极及其在碱性介质中的析氧性能

采用溶胶-凝胶法制备了钙钛矿型复合氧化物LaNiO3,然后将其加入瓦特镀镍液中进行复合电沉积,研究了镀液pH值和阴极电流密度对Ni/LaNiO3复合镀层组成的影响。运用扫描电镜(SEM)、能谱分析(EDS)和X射线衍射(XRD)等对复合镀层进行表征,结果表明:最佳电沉积工艺条件是镀液pH=5.8和阴极电流密度jk=90 mA.cm-2,所得的Ni/LaNiO3复合镀层中LaNiO3的质量含量约为60%。用循环伏安、稳态极化、恒电位阶跃、电化学阻抗谱等电化学技术评价了Ni/LaNiO3复合电极的析氧性能。结果表明:在5 mol.L-1的KOH溶液中,Ni/LaNiO3复合电极的起始析氧电位较镍电极负,表观活化自由能比镍电极降低约2/3,比表面积约为镍电极的55倍,析氧电催化性能得到大幅度提高。     

Enhanced Electrochemical Capacitive Properties of Nickel‐Cobalt Oxide Nano‐flakes Materials

Nickel‐cobalt oxide nano‐flakes materials are successfully synthesized by a facile chemical co‐precipitation method followed by a simple calcination process. The studies show that the as‐prepared nickel‐cobalt oxides with different Ni/Co ratio are composed of NiO and Co₃O₄ compounds. The Co_0.56Ni_0.44 oxide material, which exhibits a mesoporous structure with a narrow distribution of pore size from 2 to 7 nm, possesses markedly enhanced charge‐discharge properties at high current density compared with the pure NiO and pure Co₃O₄. The Co_0.56Ni_0.44 oxide electrode shows a specific capacitance value of 1227 F/g at 5 mA/cm², which is nearly three times greater than that of the pure NiO electrode at the same current density.     

Review and prospect of layered lithium nickel manganese oxide as cathode materials for Li-ion batteries

Layered structural lithium metal oxides with rhombohedral α-NaFeO₂ crystal structure have been proven to be particularly suitable for application as cathode materials in lithium-ion batteries. Compared with LiCoO₂, lithium nickel manganese oxides are promising, inexpensive, nontoxic, and have high thermal stability; thus, they are extensively studied as alternative cathode electrode materials to the commercial LiCoO₂ electrode. However, a lot of work needs to be done to reduce cost and extend the effective lifetime. In this paper, the development of the layered lithium nickel manganese oxide cathode materials is reviewed from synthesis method, coating, doping to modification, lithium-rich materials, nanostructured materials, and so on, which can make electrochemical performance better. The prospects of lithium nickel manganese oxides as cathode materials for lithium-ion batteries are also looked forward to.     

Electrochemical characterization of Ni-Co and Ni-Co-Fe for oxidation of methyl alcohol fuel w ith high energetic catalytic surface*简

 Non Pt based metals and alloys as electrode materials for methyl alcohol fuel cells have been investigated with an aim of finding high electrocatalytic surface property for the faster electrode reactions. Electrodes were fabricated by electrodeposition on pure Al foil, from an electrolyte of Ni, Co, Fe salts. The optimum condition of electrodeposition were found out by a series of experiments, varying the chemistry of the electrolyte, pH valve, temperature, current and cell potential. Polarization study of the coated Ni-Co or Ni-Co-Fe alloy on pure Al was found to exhibit high exchange current density, indicating an improved electro catalytic surface with faster charge-discharge reactions at anode and cathode and low overvoltage. Electrochemical impedance studies on coated and uncoated surface clearly showed that the polarization resistance and impedance were decreased by Ni-Co or Ni-Co-Fe coating. X-ray diffraction (XRD), energy dispersive X-ray spectroscopy (EDX) and atomic absorption spectroscopy (AAS) studies confirmed the presence of alloying elements and constituents of the alloy. The morphology of the deposits from scanning electron microscope (SEM) images indicated that the electrode surface was a three dimensional space which increased the effective surface area for the electrode reactions to take place.     

正极集流体对可充镁电池电化学性能的影响

以目前常用的Chevrel相Mo₆S₈作为正极材料, 涂覆在不同集流体(不锈钢、镍、铜、钛) 上, 以镁为负极,研究了在(PhMgCl)₂-AlCl₃/四氢呋喃(简称THF)“二代”电解液中集流体对可充镁电池电化学性能的影响. 恒流放电-充电结果显示在不锈钢集流体上电池电压极化最小, 并且具有较好的循环稳定性; 镍、铜次之; 钛集流体上的极化最大, 循环稳定性也最差. 并通过对比放电-充电循环前后电极和集流体表面的微观结构, 探讨了集流体对电池性能显著影响的原因. 电解液对集流体会造成腐蚀, 不同集流体在电解液中的稳定性有差异; 正极材料涂覆在不同集流体上, 电极表面状况有差异; 负载活性材料后集流体发生腐蚀的电位有所降低, 使集流体更易受到电解液的腐蚀.     

Ni/PdO/RuO_2复合型活性阴极的制备与表征

采用热分解氧化法,在Ni基体上制备以PdO为中间层、RuO2为活性层的Ni/PdO/RuO2复合型活性阴极,并通过XPS、XRD、能量色散X荧光(EDXRF)、SEM、极化曲线、循环伏安法和交流阻抗谱等表征其组成、结构与电化学性能。结果表明,Pd和Ru分别以PdO和RuO2的形式存在于Ni/PdO/RuO2复合型活性阴极中,其含量分别为1.25wt%和1.71wt%;在363K、11mol·L-1NaOH溶液、3kA·m-2电流密度下,Ni/PdO/RuO2复合型活性阴极的析氢过电位比Ni电极和Ni/RuO2电极分别低371和125mV;循环伏安法循环72h后,该复合型活性阴极双电层电容值减小30.6%,比Ni/RuO2电极表层结构更稳定;Ni/PdO/RuO2复合型活性阴极的表面粗糙度大且无明显的裂纹存在,与纯镍电极相比,该复合型活性阴极比表面积增加了31.12倍。     

TiO2修饰La0.6Sr0.4Co0.2Fe0.8O3-δ用于中温固体氧化物燃料电池的阴极

纳米TiO2修饰的La0.6Sr0.4Co0.2Fe0.8O3-δ(LSCF)阴极被直接应用于YSZ电解质电池上. TiO2可阻止LSCF和YSZ间的化学反应,抑制SrZrO3的形成. LSCF-0.25 wt% TiO2阴极电池在0.7 V和600°C下的电流密度是LSCF阴极电池的1.6倍.电化学阻抗谱结果表明, TiO2修饰显著加快了氧离子注入电解质的过程,这可能与TiO2抑制了阴极/电解质界面处高电阻SrZrO3层的形成有关.本文为在ZrO2基电解质上使用高性能的(La,Sr)(Co,Fe)O3阴极材料提供了一种简单有效的方法.     

Hydrothermal Synthesis of Nickel Oxide Nanosheets for Lithium‐Ion Batteries and Supercapacitors with Excellent Performance

Nickel oxide nanosheets have been successfully synthesized by a facile ethylene glycol mediated hydrothermal method. The morphology and crystal structure of the nickel oxide nanosheets were characterized by X‐ray diffraction, field‐emission SEM, and TEM. When applied as electrode materials for lithium‐ion batteries and supercapacitors, nickel oxide nanosheets exhibited a high, reversible lithium storage capacity of 1193 mA h g^?1 at a current density of 500 mA g^?1, an enhanced rate capability, and good cycling stability. Nickel oxide nanosheets also demonstrated a superior specific capacitance of 999 F g^?1 at a current density of 20 A g^?1 in supercapacitors.     

Electrochemical corrosion behaviors and corrosion protection properties of Ni–Co alloy coating prepared on sintered NdFeB permanent magnet

In this study, a protective Ni–Co alloy coating was prepared on sintered NdFeB magnet applying electrodeposition technique. A pure nickel coating was also studied for a comparison. The microstructure, surface morphologies, and chemical composition of coatings were investigated using X-ray diffraction, scanning electron microscope, and energy dispersive spectroscopy, respectively. The corrosion protection properties of coatings for NdFeB magnet in neutral 3.5 wt.% NaCl solutions were evaluated by potentiodynamic polarization and electrochemical impedance spectroscopy (EIS) techniques. The microstructure and surface morphologies analysis showed that the addition of cobalt element into matrix metal Ni altered the preferential orientation of pure nickel coating from (2 0 0) crystal face for pure nickel coating to (1 1 1) crystal face for Ni–Co alloy coating, and made the surface morphologies more compact and uniform due to the grain-refining. The results of potentiodynamic polarization test showed that compared with pure nickel coating, Ni–Co alloy coating exhibited much nobler corrosion potential (E _corr) and lower corrosion current density (j _corr), indicating better anticorrosive properties. The long-term immersion test by dint of EIS indicated that the Ni–Co alloy coating still presented high impedance value of 1.9 × 10⁵ Ω cm² with the immersion time of 576 h indicating the excellent anticorrosive properties, and corrosion protection properties of nickel coating for NdFeB magnet practically disappeared with the immersion time of 144 h, which also indicated that the Ni–Co alloy coating provided better corrosion protection properties for the NdFeB magnet compared with nickel coating.