Cu[C5H3N(CCH3=N-C6H5)2]2(PF6)2配合物的合成、晶体结构和热分解反应动力学

The title complex Cu[C₅H₃N(CCH₃=N-C₆H₅)₂]₂(PF₆)₂ has been synthesized by reaction of Schiff base C₅H₃N(CCH₃=N-C₆H₅)₂ and cupric sulfate in toluene solution. The crystal structure was determined by X-ray diffraction method and the chemical formula weight of the complex is 1041.85. The crystal structure belongs to triclinic system with space group P1 and cell parameters: a=12.6470(10)?, b=14.123(2)?, c=15.613(2)?;α=66.150(10)°,β=79.470(10)°,γ=78.290(10)°, V=2481.6(5)?³, Z=2, D_c=1.394Mg·m^-3 and F(000)=1064. The final R[I >2σ(I)]:R₁=0.0668, wR₂=0.1927; R(all data): R₁=0.1133, wR₂=0.2357. The Cu(Ⅱ) was coordinated by six nitrogen, at the same time the Cu(Ⅱ) formed a distorted octahedron, besides the angles and planes of this compound were discussed . The result of kinetics of the thermal decomposition indicated that the first step of it is 2 series chemical reactions, the function of machanism is f(a)=(1-a)², and the activation energy is 144.64E/kJ. CCDC: 180872.     

2-巯基乙磺酸铜配位聚合物的合成与晶体结构

以2-巯基乙磺酸钠为配体,2,2'-联吡啶,4,4'-联吡啶为辅助配体,与硝酸铜反应,得到一种一维链状配位聚合物 [CuL(4,4'-bipy)(2,2'-bipy)H2O]n (L=-O3S-CH2-CH2-S-S-CH2-CH2-SO-3),通过元素分析、红外光谱对其进行了表征,并用X射线衍射测定了其结构.结果表明:该配合物属于单斜晶系,P2(1)/c空间群,晶胞参数为:a=0.8385(2) nm,b=1.3764(3) nm,c=2.1719(5) nm,β = 93.391(3) °,V = 2.5023(10) nm3,Z = 4.     

乙醇在Pt/PMo12-CNTs/石墨电极上的电催化氧化

采用碳纳米管(CNTs)、磷钼酸(PMo12)修饰石墨电极,然后通过循环伏安法(CV)电沉积Pt,获得Pt/PMo12-CNTs/石墨电极.利用傅立叶变换红外光谱(FT-IR)、扫描电子显微镜(SEM)分别对改性CNTs结构及电极的形貌进行表征,通过CV、计时电流法考察了该电极对乙醇的电催化氧化性能.结果表明在催化剂Pt沉积量相当情况下,Pt/PMo12-CNTs/石墨电极较Pt/石墨电极具有更好的电催化活性和稳定性,表明PMo12改性CNTs是乙醇氧化电催化剂的良好载体.     

铂修饰聚苯胺-聚硫堇复合电极对甲醇的电催化氧化

苯胺(An)与硫堇(Tn)电化学聚合于石墨电极上,并采用电化学方法沉积Pt颗粒,制备得到Pt/PAni-PTn/石墨电极.通过扫描电子显微镜(SEM)对其形貌进行表征,利用循环伏安法(CV)、计时电流法(CA)考察了Pt/PAni-PTn/石墨电极对甲醇的电催化性能.实验结果表明,Pt颗粒均匀地分散在PAni-PTn复合膜上,PAni-PTn载体更有利Pt纳米颗粒的分散和粒径的减小,Pt/PAni-PTn/石墨电极对甲醇的电催化活性和稳定性明显优于Pt/石墨电极.     

无机实验合成产物再利用 促进实验室绿色化建设

无机化学实验是一门基础实验课程,其中大量的实验合成产物常常被弃置或排放,既浪费资源又污染环境,有效减少无机实验室污染是我们急待解决的问题。在开放实验教学中以绿色化学的原则为宗旨,对无机实验合成产物再利用,可促进实验室绿色化建设。     

乙二胺接枝改性碳纳米管负载的乙醇氧化电催化剂Pt及Pt-Ru的制备及电催化性质

采用化学法制备了乙二胺接枝改性碳纳米管（ED/MWNTs）负载的Pt及Pt-Ru催化剂,并用红外光谱法、透射电镜分析（TEM）及X射线能谱技术对催化剂进行了表征。结果表明：乙二胺对碳纳米管的改性使Pt及Pt-Ru在碳管上的分布更均匀,粒径更小。同时,催化剂对乙醇电催化氧化活性的电化学研究结果表明：乙二胺改性可明显提高Pt-Ru/MWNTs/C 和Pt/MWNTs/C的电催化活性,而且Pt/ED/MWNTs/C的活性甚至比Pt-Ru/MWNTs/C的活性还高。由此,ED/MWNTs作为乙醇电氧化催化剂的载体有着很好的应用前景。     

不同磺酸掺杂聚苯胺的制备及在超级电容器中的应用

以MnO₂为氧化剂,采用乳液聚合法,用三种不同的磺酸型表面活性剂制备掺杂聚苯胺(PANI)。通过扫描电子显微镜(SEM)、傅里叶变换红外(FTIR)光谱以及X射线衍射(XRD)等手段对其结构及形貌进行表征;用所得的掺杂聚苯胺制作电极,组装成对称扣式超级电容器,用循环伏安法(CV)、电化学阻抗(EIS)和恒电流充放电技术进行电化学性能研究。结果表明,磺酸表面活性剂的引入有利于PANI纳米纤维的形成和分散,掺杂Nafion的PANI纤维直径在30-40 nm之间,纤维交织成多孔的疏松结构;当放电电流为0.1 A·g^-1时,以PANI-Nafion、PANI-SDS(十二烷基磺酸钠)、PANI-SDBS(十二烷基苯磺酸钠)为电极材料的超级电容器比容量分别为385.3、359.7、401.6 F·g^-1,均高于未掺杂PANI的比容量(235.8 F·g^-1);其中, PANINafion的循环稳定性最好, 1000次循环后其比容量保持率高达70.7%。     

[Ni(C_5H_5N)_2(C_7·H_6O_2N)_2]H_2O三元配合物的合成及晶体结构

合成了标题化合物。该化合物的分子式[Ni(C5H5N)2(C7H6O2N)2]H2O(C24H24N4NiO3),分子量475.18,采用单色的MoKα (λ = 0.71073 )射线测定,共收集7408个数据,其中独立衍射点2567个(Rint = 0.0272),I > 2s(I)可观测点数1926个,结果表明该化合物属单斜晶系, 空间群C2/c其晶胞参数为: a = 14.466(2),b = 12.193(2),c = 14.072(2) ;β = 116.229(2)°,V = 2226.6(5) 3,Z = 4,Dc = 1.418 g/cm3 ,μ = 0.905 mm-1,F(000) = 992. 2个水杨醛亚胺各提供2个配位原子参与配位,2个吡啶各提供1个配位原子参与配位,该配合物是六配位的八面体构型,同时讨论了该体系中不同配位原子的配位能力的差异。     

高脱乙酰度、低粘度壳聚糖的研制

利用相转移催化剂与均匀设计探讨了高脱乙酰度、低粘度壳聚糖的制备方法，找出了最佳工艺条件，在最佳工艺条件下得到了粘度为２６．６ｍＰａ．ｓ，脱乙酰度为９９．４％的壳聚糖。     

Cu(Ⅱ)-牛磺酸缩水杨醛席夫碱-邻菲咯林三元配合物的合成、晶体结构及性质

The title complex was synthesized by reaction of taurine salicylic schiff base(TSSB), O-phenanthroline(phen) and cupric acetate in water-ethanol solution. The crystal structure was determined by X-ray diffraction method and the chemical formula weight of the complex is 498.00. The crystal structure of the title complex belongs to orthorhombic system with space group Pbcn and cell parameters: a=3.107 2(4) nm, b=1.289 09(18) nm, c= 1.034 78(14) nm; and V=4.144 7(10) nm³, Z=8, D_c=1.596 g·cm^-3, μ=1.197 mm^-1, F(000)=2 048. The compound is an one-dimensional chain complex of infinite length which are connected with hydrogen bonds. The Cu(Ⅱ) was coordinated by two oxygen atoms and three nitrogen while the o atoms of Ac- groups did not participate in the coordination. The Cu(Ⅱ) formed a distorted tetragonal pyramid and the capacities of coordination to Cu(Ⅱ) of atoms was discussed. Besides, the TG-IR of the complex was analyzed. The kinetics of the thermal decomposition reaction of the complex was studied under a non isothermal condition by TG-IR. TG and DTG curves indicate that the complex decomposed in three stages: (?) The kinetic parameters were obtained from the analysis of TG,DTG cures by OZAWA-Flynn-Wall method, and the activation energy and the value of A of the three stages are 74.98 kJ·mol^-1, 286.65 kJ·mol^-1, 87.55 kJ·mol^-1; 9.66×10⁸ s^-1,1.82×10²⁸ s^-1, 3.09×10³s^-1, respectively.