Pt-SO_(4)^(2-)/ZrO_(2)-WO_(3)固体超强酸催化剂的制备及其异构化性能评价

在Pt-SO_(4)^(2-)/ZrO_(2)固体超强酸中引入WO_(3)制备了Pt-SO_(4)^(2-)/ZrO_(2)-WO_(3)固体超强酸催化剂,采用N 2吸附-脱附、XRD、TPD、TPR和Py-IR等手段对所制备催化剂进行了分析表征;在5 mL连续固定床反应装置上,考察了WO_(3)含量对Pt-SO_(4)^(2-)/ZrO_(2)-WO_(3)催化剂作用下正己烷临氢异构化反应活性的影响。结果表明:WO_(3)的引入能够显著调节Pt-SO_(4)^(2-)/ZrO_(2)-WO_(3)催化剂中四方晶相ZrO_(2)含量、比表面积、孔体积、平均孔径和酸量等,使暴露在催化剂表面的活性中心明显增加;在反应温度240℃、反应压力2.0 MPa、体积空速1.0 h-1、氢气/正己烷体积比600的条件下,WO_(3)质量分数16%的Pt-SO_(4)^(2-)/ZrO_(2)-WO_(3)催化剂的异构化活性最高,正己烷转化率为82.27%,异构化率为81.32%,二甲基丁烷选择性为34.28%。

基于球磨法制备的WO_(3)敏感电极的NH_(3)传感器

采用球磨法预处理了WO_(3)颗粒并将其作为敏感电极,将钇稳定的氧化锆(YSZ)作为固体电解质制备了混合位型NH_(3)传感器。采用X射线衍射仪(XRD)和扫描电子显微镜(SEM)对预处理的材料进行了表征。经球磨法处理的WO_(3)粉末颗粒尺寸减小,比表面积增大。以WO_(3)为敏感电极,在550~700℃内对传感器的响应-恢复特性、循环稳定性、湿度和氧气体积分数的干扰、交叉气体干扰等敏感性能进行了测试。敏感性能测试结果表明:该传感器在550~700℃之间表现出优异的NH_(3)敏感性能,响应信号与NH_(3)体积分数的对数之间线性关系良好。同时该传感器还表现出良好的循环稳定性,在不同氧气体积分数和湿度的气氛下都能稳定工作。此外,该传感器对CO_(2)、H_(2)、CH_(4)和NO均表现出良好的抗干扰能力,且采用CuO参比电极成功降低了对NO_(2)的交叉干扰。

乙醇在碳载纳米Pt及纳米Pt-WO_3电极上的催化氧化

将纳米Pt/玻碳和纳米Pt -WO3 /玻碳电极应用于乙醇的电催化氧化 ,发现所制备的催化剂电极具有较高的电催化活性。

碳载纳米Pt及纳米Pt-WO_3电催化剂的制备与表征

通过电化学方法 ,在碳载体表面沉积了纳米Pt及纳米Pt WO3 表面电催化剂。运用循环伏安和扫描电子显微镜技术对催化剂电极进行了表征。结果表明 :电沉积的碳载Pt电催化材料是粒度均匀的纳米颗粒。碳载Pt WO3 电催化材料是由纳米颗粒组成的柱状结构 ,直径均匀 ,定向平行排列 。

电化学模板法制备Pt-WO_3纳米线有序阵列

通过恒电势共沉积的方法,用银作为导电基底的多孔阳极氧化铝膜(Al2O3/Ag)为模板制备了PtWO3纳米线有序阵列。利用扫描电子显微镜(SEM)、透射电子显微镜(TEM)和能量色散X射线分析(EDAX)对纳米线进行了表征。结果表明,纳米线呈直立状态,直径约为30nm,纳米线中Pt和W的质量比为m(Pt)∶m(W)=19.6∶1,原子的量比为n(Pt)∶n(W)=18.5∶1。这种PtWO3纳米线有序阵列具有很大的比表面积,可用于有机小分子的电催化氧化。

WO_(3)/Pt复合薄膜的制备及其光电催化性能

导电玻璃作为基底水热法生长了WO_(3)纳米棒,通过电沉积法改变沉积Pt的时间(40 s,80 s,120 s),以WO_(3)纳米棒为基底沉积得到不同的WO_(3)/Pt复合薄膜样品。通过X射线衍射分析和扫描电子显微镜等测试手段将WO_(3)纳米棒薄膜和WO_(3)/Pt复合薄膜样品进行表征。结果表明成功制备了WO_(3)/Pt复合薄膜样品。漫反射结果显示WO_(3)/Pt复合薄膜与WO_(3)薄膜相比具有更强的光吸收。交流阻抗谱显示WO_(3)/Pt复合薄膜与WO_(3)纳米棒薄膜相比增强了电荷转移效率。利用光电流、光电催化对WO_(3)/Pt复合薄膜进行光电性能测试,结果表明WO_(3)/Pt复合薄膜相较于单一WO_(3)薄膜光电流活性更高和光电催化活性更强,并且沉积时间为80 s的WO_(3)/Pt复合薄膜显示最为优异的光电流和光电催化性能。同时,沉积时间为80 s的WO_(3)/Pt复合薄膜的光电催化性能优于其光催化和电催化性能。

新型电催化剂Pt-WO_3电极的制备与催化活性研究

研究了制备条件对ＰｔＷＯ３电极催化活性的影响，并探讨其作用机理。ＰｔＷＯ３电极的催化活性由电极的组成和电极的微观表面结构所决定。

对丙酮高气敏选择性的Pt纳米颗粒修饰的NiWO_(4)/WO_(3)异质结构纳米管

以聚苯乙烯(PS)纳米纤维为模板,采用简单的自组装法制备异质结构NiWO_(4)/WO_(3)(Ni/W)纳米管。采用超声混合法获得Pt修饰的NiWO_(4)/WO_(3)复合纳米管(Pt@Ni/W)。结果表明,气敏性能从高到低依次为Pt@Ni/W>Ni/W>WO_(3)。2%Pt@Ni/W-5纳米管在375℃时对100×10−6丙酮具有最高的响应值(58.4),分别是WO_(3)和NiWO_(4)/WO_(3)纳米管的10.6和1.53倍。此外,相比于乙醇、甲醛、甲醇、氨气和甲苯,2%Pt@Ni/W-5纳米管对丙酮显示出极高的选择性。Pt修饰的NiWO_(4)/WO_(3)纳米管对丙酮表现出良好的响应性和稳定性,这归因于NiWO_(4)/WO_(3)异质结构的形成和Pt纳米颗粒的溢出效应。

WO_(3)敏感电极的制备及其性能研究

迈向微型化、集成化及具有高选择性和灵敏度的固体电解质气体传感器已成为未来的发展趋势。文章采用磁控溅射法成功制备了WO_(3)气体传感器敏感电极材料,并通过X射线衍射(XRD)、扫描电子显微镜(SEM)、X射线光电子能谱(XPS)等表征手段研究了WO_(3)的结构、成分和形貌并测试了该气体传感器对NO_(2)的气敏性能。XRD结果表明,当退火温度大于400℃时,WO_(3)出现(200)衍射峰,且该衍射峰随退火温度增加而显著增强,表明WO_(3)结晶质量增加。SEM测试结果表明,随着退火温度的升高,薄膜的晶粒尺寸逐渐增大。当退火温度达到500℃时,采用谢乐公式计算其晶粒尺寸达到23 nm。EDS结果表明,退火温度对薄膜的成分也有较大影响,O:W原子比例呈现增大趋势,由2.7增加到3.2,这与XPS结果相符合。通过高温气敏性能测试表明,所制得的WO_(3)敏感电极对NO_(2)表现出了明显的气体响应。本研究为制备微型化、高选择性和灵敏性的固体电解质气体传感器提供了一定的研究基础。

涂覆介孔型Pt/WO_(3)膜的光纤布喇格光栅氢气传感器

光纤布喇格光栅(FBG)因其响应速度快和准分布式测量等优势广泛应用于氢气测量领域。为进一步扩大氢气浓度测量范围,提出一种基于介孔型掺铂三氧化钨(Pt/WO_(3))粉末的FBG氢气传感器,并级联一个FBG传感头用以温度补偿。实验结果表明:将氢气浓度从0递增到32%,FBG的中心波长最大飘移量为320 pm,响应时间约为10 s,并且在0~14%氢气浓度范围内有较好的线性关系,灵敏度为11.69 pm/%H_(2),可以实现准分布的氢气浓度传感。

在LaNiO_3-Pt复合电极上Pb(Zr,Ti)O_3铁电薄膜及其成分梯度薄膜的制备和研究

LaNiO3 (LNO) thin films were prepared on Pt(111) / Ti / SiO2 / Si substrate by metal-organic decomposition (MOD) method. Pb(Zr,Ti)O3 ferroelectric thin films and their compositionally graded thin films were prepared on LNO / Pt / Ti / SiO2 /Si substrates by Sol-gel method. The composition depth profile of a typical up-graded film was determined by using a combination of Auger Electron Spectroscopy (ASE) and Ar Ion Etching. The results confirm that the processing method produces graded composition changes. XRD analysis showed that the graded thin films possessed composite structure of tetragonal and rhombohedral. The dielectric constants of Up-graded and Down-graded thin films were higher than that of each thin film unit. The dielectric constants were 277 and 269 at 10 kHz, respectively. The loss tangents were 0.019 and 0.018 at 10 kHz, respectively. The Hysteresis loops showed that the remanent polarizations of graded thin films were higher than that of each thin film unit, but the coercive fields were smaller. The remanent polarizations of Up-graded and Down-graded thin films were 30.06 and 26.96 μC·cm-2, respectively. The coercive fields were 54.14, 54.23 kV·cm-1, respectively. The pyroelectric coefficients of Up-graded and Down-graded thin films were 4.62, 2.51×10-8 C·cm-2·K-1 at room temperature, respectively. They were higher than that of each thin film unit.

Ru(bpy)_3^(2+)-C_2O_4^(2-)-PtE体系的两条电致化学发光通道

运用电位分辨电致化学发光 (PRECL)手段发现Ru(bpy) 2 + 3 C2 O2 -4 PtE体系在预氧化的多晶铂电极上存在两个发光通道 ,这两个通道分别位于 1.2 2V和 1.40V处 .对影响两发光通道的条件进行了研究 ,比较了几种经过不同预处理方式 (直接抛光、阳极极化和阴极极化的电极以及S吸附电极 )以及体系中不同C2 O2 -4 浓度 ,pH ,溶解氧和溶解二氧化碳对两PRECL峰形、峰强度的影响 .提出第二个ECL发光峰的机制为C2 O2 -4 直接电极氧化产物CO2 -·(或C2 O4 -·)的催化发光 .

Cs_(x)WO_(3)/SiO_(2)复合气凝胶的结构调控及其吸附/光催化性能

为充分利用SiO_(2)气凝胶的优异吸附性能和Cs_(x)WO_(3)的光催化性能,通过一锅溶剂热法制备Cs_(x)WO_(3)/SiO_(2)复合气凝胶,并研究了贵金属Pt掺杂对其结构及吸附/光催化性能的影响。采用XRD、SEM、TEM和BET对制备的复合气凝胶进行晶相、微观结构和孔结构分析;通过傅里叶红外光谱仪分析复合气凝胶表面官能团;利用多功能光化学反应仪及紫外可见分光光度计测试其吸附/光催化性能。结果表明,复合气凝胶的主晶相为Cs_(0.20)WO_(3),且具有介孔结构,Pt掺杂有利于增强Cs_(x)WO_(3)/SiO_(2)复合气凝胶的光催化能力,对罗丹明B表现出较好的吸附/光催化活性。

Z型g-C_(3)N_(4)/Pt/TiO_(2)纳米管阵列复合电极的制备及光电氧化甲醇性能

以NH4Cl为气体模板吹制双氰胺制备g-C3N4纳米片,并将其负载于Pt/TiO2纳米管阵列(Pt/TiO2 NTs)上,制备了一种新型的Z型g-C3N4/Pt/TiO2NTs复合电极材料.通过扫描电子显微镜、X射线衍射和X射线光电子能谱对该材料的结构进行了表征,采用电化学和光电化学方法研究了材料的性能.研究结果显示,在可见光照射下,g-C3N4/Pt/TiO2 NTs复合材料具有高效的光电氧化甲醇的性能.该复合材料的高性能主要归因于以下两点:(1)g-C3N4与Pt/TiO2NTs的结合有效扩展了其在可见光范围的吸收;(2)Z型电荷转移保留了具有强氧化能力的空穴和强还原能力的电子,从而使光生中间体作用于电催化过程增强了甲醇氧化效率.

纳米TiO_2-Pt修饰电极的制备及电催化活性

采用电化学合成前驱体直接水解法和电沉积法制备高活性纳米TiO2-Pt修饰电极,并使用扫描电子显微镜(SEM)对电极的表面形貌和结构进行了表征;通过循环伏安法研究了纳米TiO2-Pt修饰电极在H2SO4溶液中的电化学行为以及对Mn2+氧化为Mn3+的电催化活性.结果表明,纳米TiO2的晶粒大小约30nm,修饰在纳米TiO2膜表面的Pt微粒呈现单分散状态,平均粒径约60nm,纳米TiO2-Pt修饰电极的电化学性能优于纯Pt电极,对Mn2+的电氧化具有高催化活性,非均相无隔膜电解氧化Mn2+生成Mn3+平均电流效率可达86%.

Enhanced plasmonic absorption of Pt cuboctahedra-WO_(3)nanohybrids used as visible light photocatalysts for overall water splitting

Localized surface plasmon resonance(LSPR)effects of nanoscale plasmonic metals/semiconductor composites have been extensively applied into visible light photocatalysis.However,Pt nanoparticles(NPs)with the visible LSPR absorption maxima have rarely been used as a photosensitizer to facilitate photocatalytic reactions,especially the photocatalytic overall water splitting(POWS)reaction,presumably because they feature weak light absorption.Herein,we present that the increased plasmonic absorption and local field enhancement can be achieved in the wide visible range by exploiting the simulated and experimental expressions of Pt nanocuboctahedra and Pt cuboctahedra-WO_(3)nanohybrids(Pt-WO3).First,monodisperse Pt cuboctahedra with different sizes,a hierarchical WO_(3)nanoarchitecture composed of radially patterned WO_(3)nanopillars,and Pt-WO_(3)were systematically synthesized.Subsequently,visible plasmonic Pt-WO_(3)photocatalysts were employed in the POWS tests and exhibited the significant activity enhancement in the visible light region.The apparent quantum efficiency(AQE)of greater than 7%within the range of visible light has been achieved for the optimal Pt-WO3.

Pt-WO_(3)纳米氢敏薄膜的制备及传感特性研究

采用钨粉过氧化聚钨酸法制备三氧化钨溶胶,并掺杂氯铂酸。采用旋涂法制备含有铂的氢致变色三氧化钨(Pt-WO_(3))纳米薄膜。采用X射线衍射仪、场发射扫描电子显微镜和X射线能谱分析等方法分析薄膜的性质,测试结果表明:薄膜为非晶态;薄膜表面平整,没有凸起及裂痕,金属单质铂均匀分布在薄膜表面;薄膜表面均匀分布着三氧化钨分子,呈疏松多孔结构。搭建透射式光纤氢气传感系统,当氢气分子存在时,掺杂铂的三氧化钨薄膜在铂的催化下发生化学反应,进而改变薄膜的折射率,通过测试透射光强变化情况反演氢气浓度。研究结果表明,匀胶机转速为3100 r/min、旋涂时间为60 s、退火温度为400℃、退火时间为60 min的条件下制备的Pt-WO_(3)薄膜,在体积分数5%的H_(2)下通氢响应时间约为62 s,通氢前后信号响应幅值变化率约为91.54%,并且该薄膜具有良好的重复性和稳定性。

掺铂/聚3-甲基噻吩修饰电极研究氨酪酸对大鼠脑纹状体中单胺类神经递质影响

氨酪酸(GABA)是哺乳动物中枢神经系统中重要的抑制性神经递质。本研究探讨了外源性GABA对单胺类神经递质及其代谢产物的影响。研制了一种新型掺铂/聚3-甲基噻吩玻碳修饰电极,利用原子力显微镜(AFM)对该电极进行了表征,通过循环伏安法(CV)和微分脉冲伏安法(DPV)研究了单胺类神经递质及其代谢产物在该修饰电极上的电化学行为,结果表明:该修饰电极对单胺类神经递质及其代谢产物有显著的催化作用,电极的灵敏度高,稳定性和重现性好。在液相色谱电化学检测实验中,去甲肾上腺素(NE)、多巴胺(DA)、3,4-二羟基苯乙酸(DOPAC)、5-羟色胺(5-HT)和5-羟吲哚乙酸(5-HIAA)在修饰电极上的电流响应灵敏。5种被测物的检测线性范围宽达3个数量级以上,检出限分别为2.0×10-10mol/L(NE)、1.0×10-10mol/L(DA)、3.0×10-10mol/L(DOPAC)、4.0×10-10mol/L(5-HT)和7.0×10-10mol/L(5-HIAA)。将该方法与微渗析活体取样技术联用,研究了GABA对大鼠脑纹状体中单胺类神经递质及其代谢产物的影响。

Self-supported porous heterostructure WC/WO_(3−x)ceramic electrode for hydrogen evolution reaction in acidic and alkaline media

Tungsten carbide(WC)-based materials are widely considered as the hydrogen evolution reaction(HER)process catalysts due to their“Pt-like”electronic structure.Nonetheless,traditional powder electrodes have a high cost,and display problems related to the process itself and the poor stability over operation time.This paper presented a self-supported asymmetric porous ceramic electrode with WO_(3-x)whiskers formed in situ on the walls of the finger-like holes and membrane surface,which was prepared by combining phase inversion tape-casting,pressureless sintering,and thermal treatment in a CO_(2) atmosphere.The optimized ceramic electrode displayed good catalytic HER activity and outstanding stability at high current densities.More specifically,it demonstrated the lowest overpotentials of 107 and 123 mV and the lowest Tafel slopes of 59.3 and 72.4 mV·dec^(-1)at 10 mA·cm^(-2)in acidic and alkaline media,respectively.This superior performance was ascribed to the structure of the ceramic membrane and the charge transfer efficiency,which was favored by the in situ developed WC/WO_(3-x)heterostructure and the oxygen vacancies.

Improved sensing performance of WO_(3) nanoparticles decorated with Ag and Pt nanoparticles

Gas sensors built with metal oxide semiconductors have attracted tremendous attention due to the growing demand for the detection of inflammable,explosive and toxic gases.Herein,to improve the sensing response,WO_(3) nanoparticles decorated with Ag and Pt bimetals(Ag and Pt/WO_(3) NPs)have been developed via combined hydrolysis and hydrothermal strategies.Such sensors prototypes show high response to acetone(Ra/Rg=250@100×10^(-6),140℃),which is 6.1 fold as high as that of the pristine WO_(3) NPs(Ra/Rg=41@100×10^(-6),140℃).Moreover,the recovery time of Ag and Pt/WO_(3) NPs was reduced from 138 to 13 s compared with that of the pristine WO_(3) NPs.The improved acetone sensing performance may be attributed to that the chemical and electronic sensitization of Ag and Pt to WO_(3) NPs increases adsorbed oxygen species,speeds up the reaction and thus boosts the sensing response.Our strategy that decoration of dual precious metals onto WO_(3) NPs improves the acetone sensing performance may be applied to the gas sensors of other sensing materials.