Preparation and Optimization of Porous Membrane Electrodes via Gradient Coating in Hydrogen Fuel Cell

Fuel cells are considered to be one of the ideal alternatives to traditional fossil energy conversion devices.Membrane electrodes are the core components in the hydrogen fuel cells.Our work reported the synthesis of the Pt/C catalysts with different Pt loading,and by changing the Nafion content,hot pressing temperature and hot pressing pressure,the catalyst coated membrane(CCM)spraying process was optimized.Moreover,the three-dimensional structure model of the single battery membrane electrode was studied quantitatively,and the porous membrane electrode with gradient distribution was fabricated under optimized processing conditions,with excellent electrical performance.

Electrocatalytic performance of Pt/Ru/Sn/W fullerene electrode for methanol oxidation in direct methanol fuel cell

In this work,fullerene was modified by platinum,ruthenium,tin and tungsten nanoparticles.The material was characterized by XRD,ICP-OES and TEM micrograph.The average nanoparticle size on fullerene was 5-8 nm.The application of this material was investigated as a catalyst for methanol oxidation in direct methanol fuel cell.A glassy carbon electrode was modified by Pt/Ru/Sn/W fullerene and electrocatalytic activity of the electrode toward methanol oxidation in basic medium has been demonstrated and investigated using cyclic voltammetry.The catalyst showed good reactivity for methanol oxidation.

Electrically enhanced photodegradation of an azodye(Acid Orange II) using a Pt/TiO_2 film electrode irradiating with an UV lamp

A photoelectrochemical process in the degradation of an azodye (Acid Orange II) on a Pt/TiO 2 film electrode was investigated. By using the glass device and the voltage stabilized source of direct current, decolorization ratios higher than 78% were observed during a period of 5h. Comparing this value with the sum of the decolorization ratios obtained by a sole application of electrochemical(lower than 3%) and photochemical(about 23%) procedures, a significant synergic effect between both processes was observed. The effects of adscititious voltage and pH value on the decolorization ratios were obvious while the effect of the amount of aeration was minor.

AC IMPEDANCE OF PHENYL ISO-THIOCYANATE ADSORBED ON PT ELECTRODE

The paper presents ac impedance behaviours of phenyl iso-thiocyanate adsorbed on Pt electrode.Nyquist plots are analysed and simulated,and parameters of relative equivalent circuits are obtained.

不同Pt与Ni质量比的Pt-Ni复合电极析氢性能实验

为降低PEM制氢Pt电极成本,采用电化学沉积法制备以泡沫镍为基材微量Pt沉积的Pt-Ni复合电极。采用扫描电子显微镜、X射线衍射仪、X射线光谱仪对制备的Pt-Ni复合电极进行表征,采用电化学工作站和PEM电解池对Pt与Ni质量比分别为1∶7、1∶11、1∶12、1∶14和1∶23的5种不同复合电极及泡沫镍电极的析氢性能进行电化学对比分析实验和PEM制氢对比实验。结果表明:以泡沫镍为基材,采用电化学沉积法制备的Pt-Ni复合电极性能稳定,沉积Pt质量的多少对Pt-Ni复合电极的析氢性能有较大影响;存在一个最佳Pt与Ni质量比,实验条件下的最佳Pt与Ni质量比为1∶12,沉积Pt量过多和过少都会使其析氢性能降低,过多造成的Pt沉积堆叠相比较少对析氢性能的影响更加明显。在制备微量Pt沉积的Pt-Ni复合电极时,要坚持以最佳Pt与Ni质量比为基准和沉积Pt量“宁少毋多”的原则,实际工程应用中应避免“沉积Pt量越多电极性能越好”的误区。

Preparation and electrocatalytic property of Au-Pt/SnO_2/GC composite electrode

Au-Pt/SnO2/GC composite electrode was prepared by self-assembling Au-Pt nanoparticles on SnO2 film, which was deposited on actived glassy carbon （GC）. Atomic force microscopy （AFM） and scanning electron microscopy （SEM） images revealed that dense and uniform Au-Pt particles with 25-nm diameter were dispersed on SnO2 film. X-ray photoelectron spectroscopy （XPS） results proved that there was an interaction between Au-Pt nanoparticles and SnO2 support. Electrochemical experiments showed that Au-Pt/SnOz/GC composite electrode had a good electrocatalytic activity to the oxidation of methanol

An Unusually High Sensitivity of Pt-black pH Electrode

The potentials of Pt-black electrode using a copper conducting wire instead of the salt bridge in acid and alkaline solutions without the use of H2 evolution reactions were measured. There were three nonlinear portions in the calibration curve. Unusually, the potential slopes at pH 3-5 and 8-10 indicated 200 mV and 70 mV per pH, respectively. Such high sensitivity for pH slope, more than 4 times of usual 59 mV per pH, may be credited to the special properties of the Pt-black surface. SEM （scanning electronical microscopy） was applied to characterize the surface of the Pt-black electrode. Its working mechanism is well explained in the theory of capacitance potentials rather than Nernst＇s redox potentials.

高温烧制时间对Pt/YSZ电极性能的影响

借助交流阻抗测试技术以及循环伏安、计时电流和扫描电镜方法,研究用Pt浆法制备Pt/YSZ电极过程中高温（850℃）烧制时间对其性能的影响。研究结果表明：在Pt/YSZ电极制作时,随着高温烧制时间的增加,电极界面阻抗和氧传感器响应时间均先减小后增大,当烧制时间为10 h时,电极阻抗最小,响应最快,活性最强;Pt/YSZ电极反应激活能受高温烧制时间的影响较小,为200~220 kJ/mol,其速率控制步骤可能为气相O2在PtOx/YSZ界面伴随电荷转移的解离过程。

Pt/YSZ电极烧制的升/降温速率对传感器性能的影响

借助交流阻抗谱测试技术和扫描电镜,研究了Pt/YSZ电极烧制的升/降温速率对氧传感器性能的影响。研究表明:升/降温速率对电极阻抗和氧传感器响应时间有显著影响;小于500℃时,升/降温速率对电极反应激活能无明显影响,为(150±10)kJ.mol-1;大于600℃时,升温速率对电极反应激活能亦无明显影响,为(180±5)kJ.mol-1,但增加降温速率,激活能会发生突变。

Pt/YSZ电极结构老化特性研究

借助于I-V极化曲线、交流阻抗测试及电子扫描电镜等技术和设备,对以Y2O3稳定ZrO2多晶固体氧离子导体(YSZ)为基体的Pt/YSZ电极结构电学性能和电极形貌随时间的老化变化特性进行了研究;为定量表述电极形貌的变化特性,作者提出了一种有关Pt/YSZ电极结构电极界面的形貌模型,采用此模型对不同老化时间下的电极Pt/空气/YSz三相界面的长度进行了定量计算.实验测试、理论模型计算等结果都表明:Pt/YSZ电极结构的电学性能和电极形貌均随老化时间出现了明显的变化.

Pt／YSZ固体电解质界面氧的电荷传递过程研究

用极化法研究了不同温度和氧分压下Ｐｔ／ＹＳＺ界面氧的电荷传递过程．研究发现氧电荷传递过程的阴、阳极电荷传递系数为１，不随温度和氧分压而变．从实验和反应机理推导得到，Ｐｔ／ＹＳＺ界面的交换电流密度和氧分压之间存在，ｉ０＝２ＦＫｒ（ＫＯ２ＰＯ２）１／４（１＋ＫＯ２ＰＯ２）１／２的关系．通过数学分析还获电化学反应速度常数。

Pt／YSZ电极烧制工艺研究

借助交流阻抗谱测试技术和扫描电镜，研究了Pt／YSZ电极烧制工艺条件对其性能的影响。研究表明，制作Pt／YSZ电极时烧结温度越高，电极阻抗越大，氧传感器响应越慢，但O2的电极还原反应速率控制步骤（〉600℃，吸附氧原子Oatm在Pt表面向YSZ的扩散过程；〈500℃，气相O2分子在Pt／YSZ界面附近的解离吸附过程）未发生变化；电极烧结的升／降温速率对电极阻抗和氧传感器响应时间有显著影响，降温速率增大还会使电极反应激活能发生突变（〉600℃，激活能由169kJ／mol突然增至（217±4）kJ／mol）；当Pt／YSZ电极工作温度〈500℃时，其最优烧制工艺为烧结温度700℃，升／降温速率0．5～1℃／min。

Pt/YSZ氧传感器的电极电阻和响应特性

应用两电极直流极化法测定了氧传感器在380～800℃中的Pt，空气／YSZ电极电阻，从交流低频阻抗测量外推法测得YSZ的体电阻，可以将YSZ的直流极化从电极的过电位中区分出来．Pt，空气｜（ZrO2）0．93（Y2O3）0．07｜空气，Pt，电池的直流极化1gI-η作图得出，电极电荷传递系数为2．YSZ体电阻、Pt，空气／YSZ电极电阻和电极交换电流对温度的Arrhenius图，在600℃和570℃附近存在着类似的活化能变化．测量表明；700℃时，氧传感器的测量响应时间2．5s．

Pt/YSZ电极结构老化特性的复阻抗研究

借助于交流复阻抗测试技术和电子扫描电镜设备,对以Y2O3稳定ZrO2固体氧离子导体(YSZ)为基体的Pt/YSZ电极结构电学性能和电极形貌随时间的老化变化特性进行了研究;根据作者提出了一种有关Pt/YSZ电极结构电极界面的形貌模型,对不同老化时间下的电极Pt/空气/YSZ三相界面的长度进行了定量计算。实验测试和模型计算等结果都表明:Pt/YSZ电极结构的电学性能和电极形貌均随老化时间出现了明显的变化。

Pt/YSZ电极结构形貌的表征

根据YSZ型氧传感器中O在电极表面的吸附、扩散以及Pt/YSZ界面O(Pt电极中)/O2(YSZ中)的传递的机理,提出了一种对Pt /YSZ电极界面进行定量表征的模型。用此模型对不同烧结温度下的电极形貌Pt/空气/ YSZ三相界面长度进行了定量表征,同时,采用复阻抗测试技术和氧传感器响应测试技术对表征结果的合理性进行了验证。理论推算和试验结果都表明:采用1 000℃,1 h烧结的电极形貌具有最佳的电化学性能。

Pt/YSZ电极结构形貌对传感器特性的影响

借助交流阻抗测试技术、汽车用A F(空气与燃料的质量比 )氧传感器响应时间测量装置及SEM ,对敏感材料为Y2 O3 稳定ZrO2 多晶固体氧离子导体 (YSZ)的Pt YSZ电极结构氧传感器其特性在不同烧结温度下电极形貌的关系进行了研究 ,同时提出了一种有关Pt YSZ电极界面的形貌模型 ,采用此模型对不同烧结温度下的电极形貌Pt 空气 YSZ三相界面长度进行了定量计算。

Pt／YSZ固体电解质界面的电化学动力学研究

用循环伏安、线性扫描等电化学方法研究了Ｐｔ／ＹＳＺ固体电解质界面的电化学行为，发现氧在Ｐｔ上的电化学吸附过程是Ｔｅｍｋｉｎ吸附过程，吸附量随时间对数增加。吸附氧的阴极还原是不可逆的过程。通过研究获得吸附氧阴极还原过程的电荷传递系数、Ｔｅｍｋｉｎ系数等重要参数。

Pt-N-TiO_(2)纳米管电极的制备及其表征

采用光化学沉积法与等离子体法制备Pt-N-TiO_(2)纳米管电极,SEM、EDS以及XRD等表征手段表明TiO_(2)纳米管管径约为90 nm,Pt纳米颗粒均匀负载至纳米管管口且未改变TiO_(2)纳米管结构。UV-Vis-DRS表明Pt-N-TiO_(2)纳米管光吸收性能在可见光区相比掺Pt前提高明显。CV、EIS电化学性能分析表明Pt-N-TiO_(2)纳米管表面电荷转移加快,具有更好的导电性能和氧化性能。通过降解目标染料甲基紫分析Pt-N-TiO_(2)纳米管的光电催化性能,在初始浓度10 mg/L,pH=3,外加偏压25 V,Pt负载浓度为1 g/L,甲基紫60 min降解率93.64%,降解过程符合一级动力学反应方程。

Pt/YSZ泵氧电极响应特性研究

以钇稳定氧化锆(简称YSZ)为固体电解质,Pt/YSZ为电极材料,制备了NOx传感器。采用计时电流法(chronoamperometry)和电化学阻抗法(EIS)研究了Pt/YSZ泵氧电极对O2和NO的响应特性。结果表明,氧气浓度基本不影响电极活化能,在相同测试温度下,随着氧气浓度的增加,泵电流呈直线增加,界面电阻降低;氧气浓度一定时,泵电流与测试温度呈指数关系。特定测试温度下,随着NO浓度增加,泵电流呈指数增长趋势,而界面电阻逐步降低。