聚乙二醇功能化双咪唑型离子液体在H_2PtCl_6催化烯烃硅氢加成反应中的应用

合成和表征了一系列聚乙二醇功能化双咪唑型离子液体,并将其应用于H2PtCl6催化烯烃硅氢加成反应中.考察了不同聚乙二醇链长、不同阴离子的离子液体以及不同反应底物对催化反应的影响.还考察了催化剂体系的稳定性,该催化体系显示了优良的重复性能.

焙烧气氛对PtSnK/Al2O3催化剂丙烷脱氢性能的影响

将H2PtCl6·6H2O和SnCl2·2H2O浸渍在球形氧化铝载体上,在不同的气氛中焙烧得到催化剂,利用XRF,XRD,NH3-TPD,H2-TPR,CO-TPR等方法分析了焙烧气氛对催化剂性能的影响。表征结果显示,焙烧气氛不影响催化剂的孔结构和晶型结构。在含氯气的空气气氛下焙烧的催化剂能保持催化剂的Cl含量,使载体酸性中心数目增加,酸量提高,且能使Pt更好地与SnOx发生相互作用而被分散。考察了不同气氛下焙烧的催化剂的丙烷脱氢性能。实验结果表明,相比在空气中和氮气中焙烧的催化剂,在含氯气的空气气氛下焙烧的催化剂的丙烷转化率明显提高,从反应初期到反应50 h内,丙烷转化率从37%下降到35%左右,丙烯选择性在96%左右。

CuPc/H_2 PtCl_6有机半导体毒气传感器的制备与性能

针对有毒有害气体的监测问题,采用有机合成工艺制备了CuPc有机半导体材料,并对其进行杂化处理和电极设计,形成了具有较佳性能的毒气传感器．以对甲基苯酚、4-硝基邻苯二晴为原材料,以N,N-二甲基甲酰胺为溶剂,在N\-2保护和碳酸钾的催化作用下合成酞菁分子碎片,再以共溶技术合成了4取代对甲苯氧基CuPc．然后,按照一定比例将CuPc和H\-2 PtCl\-6共溶在甲醇溶液中,杂化合成了有机半导体CuPc/H\-2PtCl\-6气敏材料．并采用多孔电极结构结合真空饺技术形成气敏薄膜型传感器．质谱和红外吸收光谱分析验证了合成工艺路线的正确性．电子扫描观察了多孔电极和气敏膜的微观形貌．气敏性能测试表明,CuPe/H\-2PtCl\-6对Cl\-2和H\-2S等有毒气体有较好的敏感性和选择性．

电化学石英晶体微天平研究碱性介质中单层级铂原子修饰的金电极上甲醇的电催化氧化

通过在Au电极表面欠电位沉积(UPD)Cu、再与Pt源(H2PtCl6或K2PtCl4)进行置换反应,制得单层级Pt原子修饰的金电极(对H2PtCl6或K2PtCl4,所制电极分别记为Pt(CuUPD-Pt4+)n/Au或Pt(CuUPD-Pt2+)n/Au,n表示欠电位沉积-置换过程的重复次数).用电化学石英晶体微天平(EQCM)技术定量研究了所制电极,评估了其在碱性环境中催化甲醇氧化的质量比活性(SECA).结果表明,以H2PtCl6为Pt源所制电极(Pt(CuUPD-Pt4+)3/Au)的活性更高,最大SECA高达35.7mAμg-1.根据EQCM结果计算了置换效率,籍此讨论了Pt原子在Au电极表面的层层组装结构,发现所制电极表面的裸Au位点分布百分数与实验结果(由AuOx还原峰电量测算)吻合.我们认为,EQCM技术是一种定量研究电极支撑的超薄催化剂的有效手段,这种高效的单层级贵金属催化剂有望在生物、能源、环境相关的电催化研究中进一步应用.

Electrochemical quartz crystal microbalance study on Au-supported Pt adlayers for electrocatalytic oxidation of methanol in alkaline solution

Underpotential deposition(UPD) of Cu on an Au electrode followed by redox replacement reaction(RRR) of CuUPD with a Pt source(H2PtCl6 or K2PtCl4) yielded Au-supported Pt adlayers(for short,Pt(CuUPD-Pt4+)n/Au for H2PtCl6,or Pt(CuUPD-Pt2+)n/Au for K2PtCl4,where n denotes the number of UPD-redox replacement cycles).The electrochemical quartz crystal microbalance(EQCM) technique was used for the first time to quantitatively study the fabricated electrodes and estimate their mass-normalized specific electrocatalytic activity(SECA) for methanol oxidation in alkaline solution.In comparison with Pt(CuUPD-Pt2+)n/Au,Pt(CuUPD-Pt4+)n/Au exhibited a higher electrocatalytic activity,and the maximum SECA was obtained to be as high as 35.7 mA ?g?1 at Pt(CuUPD-Pt4+)3/Au.The layer-by-layer architecture of Pt atoms on Au is briefly discussed based on the EQCM-revealed redox replacement efficiency,and the calculated distribution percentages of bare Au sites agree with the experimental results deduced from the charge under the AuOx-reduction peaks.The EQCM is highly recommended as an efficient technique to quantitatively examine various electrode-supported catalyst adlayers,and the highly efficient catalyst adlayers of noble metals are promising in electrocatalysis relevant to biological,energy and environmental sciences and technologies.