衬底加热和电极修饰对提高有机场效应晶体管性能的影响

通过衬底加热和氧化钼(MoO3)修饰源漏极制备了并五苯有机场效应晶体管.研究了衬底温度和电极修饰层厚度对器件性能的影响.实验结果表明:当衬底温度为60℃、MoO3修饰层为10 nm时,器件性能获得了显著增强,场效应迁移率由原来的3.39×10-3 cm2/(V·s)提高到2.25 ×10-1 cm2/(V·s),阈值电压由12 V降低到3V.器件性能的改善归因于:衬底加热可以优化有源层形貌,改善载流子传输;而MoO3修饰层显著降低了电极与有源层之间的接触势垒,提高了载流子的注入.因此,衬底加热与电极修饰对于制备高性能有机场效应晶体管是不可或缺的优化手段.     

旋涂速度对制备P3HT有机场效应晶体管性能的影响

采用溶液化的方法制备了以PMMA为绝缘层、P3HT为有源层的有机场效应晶体管.研究了P3HT有源层和PMMA绝缘层的旋涂速度对器件性能的影响.实验结果表明,当P3HT和PMMA的旋涂速度均为2 000 r/min时,器件的性能最佳.峰值场效应迁移率为6.84×10^-2 cm²·V^－1·s^－1.结果表明,选择适当的旋涂速度是一种有效提高溶液化制备有机场效应晶体管性能的方法.     

多孔碳材料的化学气相后处理及其超级电容性能

以廉价的椰壳为原料制备了高比表面积的多孔碳材料,然后在密闭的反应釜中以硝酸蒸汽对多孔碳材料进行了后处理,制备了亲水性更好的多孔碳材料。采用扫描透射电子显微镜(TEM)、物理吸附、X射线粉末衍射(XRD)、拉曼光谱(Raman)和接触角测试对材料的微观形貌、孔道结构、组成和亲水性进行了表征,探究了不同温度下硝酸蒸汽对多孔碳材料的形貌、结构的影响,并采用循环伏安法、恒电流充放电法和交流阻抗法考察了多孔碳材料的超级电容性能。结果表明,经过硝酸蒸汽处理后的多孔碳材料的比表面积和孔体积均有所降低,且随着处理温度的升高,降低得更加明显,而亲水性却越来越好。电化学测试结果表明,经过100℃硝酸蒸汽处理的多孔碳材料(CSC-100)具有最佳的超级电容性能。在以6 mol·L^-1 KOH为电解液的三电极体系中,当电流密度为0.5 A·g^-1时CSC-100的比电容可达452.9 F·g^-1,而未经硝酸蒸汽处理的多孔碳材料(CSC)的比电容仅为350.4 F·g^-1。电容贡献分析表明CSC-100良好的亲水性和表面官能团不仅提高了双电层电容,也提高了赝电容。     

基于原油中金刚烷指纹半定量分析进行原油鉴别

采用气相色谱质谱联用(GC-MS)技术,建立了原油中金刚烷化合物内标法半定量的分析方法,确定了基于谱图特征和计算保留指数的组分定性方法,对26种单金刚烷、双金刚烷化合物进行了定性与定量分析.对不同地理位置海上油井平台6个原油金刚烷指纹进行了分析.研究表明,原油中单金刚烷总含量在200～1200 μg/g之间,双金刚烷总...     

化学链燃烧中CaSO4复合载氧体的实验研究

采用浸渍法制备CaSO4复合载氧体,在固定床上进行甲烷化学链燃烧实验研究.探讨了还原温度、CH4含量、载氧体的颗粒粒径和质量等因素对还原反应的影响.结果表明,Ni-Fe混合添加剂显著提高CaSO4载氧体的反应活性;合适的还原温度为925℃左右;CH4含量的降低和载氧体质量的增加,将抑制积炭的发生,并获得较高气体转化率;...     

草酸二甲酯气相催化加氢合成乙二醇的研究

采用共沉淀法制备了一系列 CuO/SiO₂ 催化剂,进行草酸二甲酯气相加氢活性评价,分别考察了不同沉淀剂（Na₂CO₃、NH₃·H₂O、NaOH）、催化剂组成以及反应工艺条件对加氢性能的影响。采用N₂ 吸附脱附、N₂O吸附、XRD、TG热重分析、H₂-TPR等手段对催化剂进行表征。结果表明,草酸二甲酯加氢反应活性与Cu⁰有关,提高铜比表面积有利于提高加氢活性。采用以NaOH沉淀剂制备的CuO质量分数为50%的CuO/SiO₂催化剂,在200℃、2MPa、0.07h^-1和氢酯摩尔比为100时,草酸二甲酯转化率可达 98%,乙二醇选择性87%,且催化剂表现出较好的稳定性。     

Thermodynamic Properties and Relative Stability of Polyhydroxylated Dibenzo-p dioxins Calculated by Density Functional Theory

In this work, partial thermodynamic properties of polyhydroxylated dibenzo-p-dioxins (PHODDs) are calculated by density functional theory (DFT) with the Gaussian 03 program at the B3LYP/6-311G** level. By comparing the total energy Eθ values, it is found that two types of hydrogen bonds exist in PHODDs, one between a hydroxyl and the parent compound (dibenzop-dioxin) with bond energy of approximate 15.7 kJ/mol and the other between two ortho hydroxyl groups with higher bond energy of about 18.3 kJ/mol. Hydrogen bonds have an effect on the conformation stability. On the basis of evaluating the strength of these two types of hydrogen bonds, 75 most stable congeners are ascertained. The relations of calculated thermodynamic parameters (total energy Eθ, zero-point vibrational energy ZPE, correction value of thermal energy Ethθ, heat capacity at constant volume CVθ) with the number and position of hydroxyl substitution (NPHOS) are also discussed. The results show that the NPHOS models can be used to predict the thermodynamic properties for PHODD congeners. In addition, the values of molar heat capacities at constant pressure (Cp,m) from 200 to 1000 K for PHODD congeners are calculated, and the temperature dependence relation of Cp,m is obtained with the least-squares method.     

Two Zinc（Ⅱ） Carboxyarylphosphonates with Unusual Polynuclear Zn（Ⅱ） Units：Syntheses and Crystal Structures

[Zn2(PCP)(phen)(H2O)F]n 1 and {[Zn3(MCP)2(phen)2(H2O)]·2.5H2O}n 2(PCP = p-O2C(C6H4)PO33-,MCP = m-O2C(C6H4)PO33- and phen = phenanthroline) were obtained by hydrothermal synthesis and characterized by X-ray single-crystal diffraction.Compound 1 crystallizes in the monoclinic P21/c space group with a = 7.908(2),b = 20.254(3),c = 13.477(2) ,β = 107.76(3)°,V = 2055.7(8) 3,Z = 4,C20H16FN2O6PZn2,Mr = 561.10,Dc = 1.813 g/cm3,μ = 2.463 mm-1,F(000) = 1128,the final R = 0.0340 and wR = 0.0794.Compound 2 crystallizes in the monoclinic P21/n space group with a = 15.629(3),b = 18.141(4),c = 17.723(7) ,β = 121.89(2)°,V = 4267(2) 3,Z = 4,C40H31N4O13.5P2Zn3,Mr = 1041.70,Dc = 1.620 g/cm3,μ = 1.818 mm-1,F(000) = 2108,the final R = 0.0669 and wR = 0.1775.In compound 1,the tetranuclear Zn4 units are linked together by μ4-PCP3- to build 2D(4,4) layers,which are further interconnected through the μ2-bridging fluorion into a 3D framework with 1D phen ligands-filled channels.As for the 3D supramolecular framework of 2,the novel hexanuclear Zn6 units with "chair" conformation are extended by the moieties of μ4-MCP3- ligand to a 2D(4,4) layer on the bc plane,which is viewed as the 2-folded layers in 1.In both compounds,the structures are stabilized by hydrogen bonding interactions and π-π stacking interactions between the phen rings.Additionally,FT-IR spectroscopy and the fluorescent properties are discussed.     

Synthesis,Crystal Structure and Theoretical Calculation of 1,1＇,5,5＇-Tetramethyl-2,2＇-diphenyl-4,4＇-[i-phenylene-bis（methylidy-nenitrilo）]di-1H-pyrazol-3（2H）-one

1,1',5,5'-Tetramethyl-2,2'-diphenyl-4,4'-[i-phenylenebis(methylidynenitrilo)]di-1H-pyrazol-3(2H)-one was synthesized and characterized by X-ray single-crystal diffraction analysis.The crystal crystallizes in monoclinic,space group P21/c with a = 6.1375(1),b = 24.6571(4),c = 17.7487(3) ,β = 94.781(1)°,V = 2676.62(8) 3,C30H28N6O2,Mr = 504.58,Z = 4,Dc = 1.252 g/cm3,F(000) = 1064,μ = 0.081 mm-1,R = 0.0463 and wR = 0.1153(I > 2σ(I)).Theoretical studies of the title compound were carried out by density functional theory(DFT) BLYP method,using ADF program package.It indicates that N(26) and N(41) are active sites of the title compound.     

1D Lanthanide Coordination Polymers Based on 3-（Pyridin-4,yl）benzoic Acid： Syntheses, Structures and Luminescent Properties

Four novel 1D lanthanide coordination polymers with formula [Ln(3,4-pybz)3(H2O)2· H2O]n (Ln = 1 Sm; 2 Eu; 3 Tb; 4 Dy, 3,4-Hpybz = 3-(pyridin-4-yl)benzoic acid) have been synthesized by hydrothermal reactions of lanthanide oxide and 3-(pyridine-4-yl) benzoic acid. Single-crystal X-ray diffraction shows that the four compounds are isostructural. They all crystallize in a monoclinic system, space group P1. They have a doubly carboxylate-bridged infinite-chain structure with alternating Ln-(carboxylate)2-Ln linkages and one chelating carboxylate group on each metal center. The Ln ion also combines to two water molecules to form an eight-coordinate square antiprismatic geometry. The pyridine nitrogen atoms of the ligand do not coordinate to the metal centers but direct the formation of a 3D network through hydrogen bonding with coordinated water molecules. The photoluminescent properties of 2 and 3 have been also studied.