基于(R)-四氢噻唑-2-硫酮-4-甲酸盐的手性离子液体的合成及性质

在室温下将(R)-四氢噻唑-2-硫酮-4-甲酸与氢氧化N-烷基吡啶或氢氧化1,3-二烷基苯并咪唑反应,合成了6种新型手性离子液体;其结构经核磁共振波谱(1H NMR,13C NMR)、红外光谱(IR)和电喷雾质谱(ESI-MS)表征;测定了其旋光度和p H值,并对其溶解性、电导率及热稳定性进行了研究.结果表明,合成的6种离子液体均为弱酸性,室温下可溶解于极性较强的有机溶剂;当其水溶液浓度为1×10-3mol/L时,电导率随着温度的升高而增大;在150和250℃有2个失重阶段,可能是阴、阳离子分别失重的过程,热稳定性较好.     

1-(2-羟乙基)-2-烷基-咪唑啉缓蚀剂缓蚀机理的理论研究

采用量子化学计算、分子动力学模拟和分子力学相结合的方法, 对6种不同烷基链长的1-(2-羟乙基)-2-烷基-咪唑啉缓蚀剂抑制H2S腐蚀的缓蚀机理进行研究, 并对其缓蚀性能进行评价. 前线轨道分布和Fukui指数表明, 6种缓蚀剂分子的反应活性区域均集中在分子的咪唑环上, 3个反应活性中心分别位于咪唑环上的N(4), N(7)和C(8)原子, 可使咪唑环在金属表面形成多中心吸附. 分子的反应活性及活性区域分布对烷基链长并不敏感. 单分子吸附能、膜的内聚能、吸附角和链间距的计算数据显示, 缓蚀剂膜的稳定性以及膜与金属基体的结合强度随链长的增加而增大; 当正构烷基碳链长度大于13时, 缓蚀剂可在金属表面形成一层高覆盖度、致密的疏水膜, 能有效阻碍溶液中的腐蚀介质向金属表面扩散, 从而达到阻碍或延缓腐蚀的目的.     

咪唑啉缓蚀剂在Fe(001)表面吸附行为的分子动力学模拟

采用分子动力学模拟方法研究了5种不同烷基链长的咪唑啉类缓蚀剂在Fe(001)表面的吸附行为和成膜机制,并对其缓蚀机理进行了深入分析.研究结果表明:咪唑啉分子的极性头基会吸附在金属表面上,而烷基碳链则背离金属表面,并通过自身的扭转形变实现稳定吸附;随着烷基链长的增加,缓蚀剂与金属基体的结合强度逐渐增加,所形成缓蚀剂膜的致密性也逐渐增大;致密的缓蚀剂膜能有效地阻碍腐蚀介质向金属表面扩散,从而达到延缓金属腐蚀的目的.5种缓蚀剂缓蚀性能的理论评价结果与实验结果吻合.     

正、叔十二烷基硫醇在铜表面上自组装膜测试

研究了正、叔十二烷基硫醇在铜表面上的自组装及混合自组装成膜情况,并利用交流阻抗和极化曲线电化学方法测试了正、叔十二烷基硫醇在铜表面上自组装膜及混合自组装膜对铜的耐腐蚀性,考察了正十二烷基硫醇自组装膜质量与正十二烷基硫醇溶液的浓度及组装时间的关系。研究结果显示,混合自组装膜的质量及其对铜的耐腐蚀性比仅组装正或叔十二烷基硫醇均有很大的提高。     

羟基取代的烷基苯磺酸盐在水/气和水/癸烷界面的结构特点（摘要）

驱油表面活性剂的分子设计是一项重要的研究课题.设计新型高效的驱油表面活性剂关键的问题在于如何洞察表面活性剂的结构和功能的关系.长线性烷基苯磺酸盐是一类非常流行的表面活性剂,广泛应用于工业和日常生活中.关于烷基苯磺酸盐的结构和功能研究已有大量的实验和理论工作报道.近来,结合分子设计的思想,实验上合成了新型的羟基取代的烷基苯磺酸盐表面活性剂,并研究了这类新型表面活性剂动态的界面行为.我们从理论上利用分子动力学模拟的方法研究了羟基取代的烷基苯磺酸盐单分子层在水/气和水/癸烷界面的结构特点.从液体密度剖面图、氢键、表面活性剂聚集结构和有序参数等方面,详细报道了2-羟基-3-癸基-5-辛基苯磺酸钠这种新型阴离子表面活性剂的界面特征.模拟结果表明随着表面活性剂分子数目的增加,每个表面活性剂在单分子层上形成分子内氢键的平均数目将下降,但形成分子内氢键的结构仍处于主导地位;烷基尾链的疏水部分,尤其是苯环3号位上取代的癸基随着表面活性剂覆盖度增大,向界面外延伸并且更加有序;二维径向分布函数描绘了表面活性剂聚集结构的特点并暗示了癸烷相将影响表面活性剂疏水部分的取向;表面活性剂分子容易形成长程氢键结构.我们的模拟结果是对实验研究的一个重要补充.此外,模拟中我们利用gromacs和ffamber程序,使用了全原子模型,这将为模拟烷基苯磺酸盐表面活性剂的界面行为提供新的方案.     

分子结构对咪唑啉缓蚀剂膜在Q235钢表面生长和衰减规律的影响

采用弱极化法、电化学阻抗谱等手段研究了烷基咪唑啉和硫脲基烷基咪唑啉缓蚀剂对Q235钢在饱和CO2盐溶液中的缓蚀行为变化, 探讨了吸附膜的形成与衰减规律. 结果表明, 烷基咪唑啉和硫脲基烷基咪唑啉缓蚀剂都是以控制阳极过程为主的混合界面型缓蚀剂. 在85 ℃下, 烷基咪唑啉成膜相对较慢, 吸附能力较弱, 容易发生脱附; 而硫脲基的引入, 使得硫脲基烷基咪唑啉缓蚀剂溶液存在自动修复能力, 增强了咪唑啉环的吸附性能, 提高了缓蚀剂的缓蚀性能; 硫脲基烷基咪唑啉水解开环后, 成膜性能下降, 膜寿命和缓蚀效率也大大降低. 最后采用量子化学计算对上述结论进行了验证和解释.     

缓蚀剂膜抑制腐蚀介质扩散行为的分子动力学模拟

采用分子动力学模拟方法研究了4种腐蚀介质粒子(H₂O, H₃O⁺, HS^-和Cl^-)在6种不同烷基链长的1-(2-羟乙基)-2-烷基-咪唑啉缓蚀剂膜中的扩散行为. 计算了腐蚀介质粒子在不同缓蚀剂膜中的扩散系数、膜的自由体积分数、粒子与膜的相互作用能等, 并对缓蚀剂膜抑制腐蚀介质粒子扩散行为的微观机理进行了分析. 计算结果表明, 6种缓蚀剂膜均可有效阻碍腐蚀介质粒子向金属表面的扩散, 从而达到抑制或延缓腐蚀的目的; 随烷基链长的增加, 缓蚀剂膜对腐蚀介质粒子扩散行为的抑制能力逐渐增强; 同种缓蚀剂膜对正负离子H₃O⁺, HS^-和Cl^-比对中性的H₂O分子具有更强的扩散抑制能力.     

咪唑离子液体对铜在硫酸溶液中的缓蚀作用

采用动电位极化和电化学阻抗谱技术研究了三种新型烷基咪唑离子液体, 1-丁基-3-甲基咪唑硫酸氢盐([BMIM]HSO₄), 1-已基-3-甲基咪唑硫酸氢盐([HMIM]HSO₄), 1-辛基-3-甲基咪唑硫酸氢盐([OMIM]HSO₄), 对铜在0.5 mol·L_-1 H₂SO₄溶液中的缓蚀作用. 实验结果表明: 咪唑离子液体能有效抑制铜在硫酸溶液中的腐蚀, 相同浓度下的缓蚀效率大小顺序为[OMIM]HSO₄>[HMIM]HSO₄>[BMIM]HSO₄. 动电位极化表明三种咪唑化合物的加入对铜的阴阳极腐蚀过程均有抑制作用, 属于混合型缓蚀剂. 电化学阻抗谱用带两个常相位原件的等效电路对含两个时间常数的体系进行拟合, 发现咪唑化合物的添加会引起电荷传递电阻和双电层电容等阻抗参数的变化, 表明此类化合物通过吸附于铜电极与溶液界面起到缓蚀作用, 且这种吸附符合Langmuir吸附等温关系. 吸附过程热力学计算说明咪唑化合物在铜表面发生了自发的物理吸附.     

咪唑啉缓蚀剂膜抑制腐蚀介质扩散行为的MD研究

采用分子动力学模拟的方法,对5种1-(2-氨乙基)-2-烷基-咪唑啉缓蚀剂[(NH2)C2H4-C3H4N2-CH2(CH2)nCH3,n=5,7,9,11,13]抑制CO2腐蚀的缓蚀机理进行了研究.计算了4种腐蚀介质粒子(H2O,H3O+,Cl-和HCO-3)在不同缓蚀剂膜中的扩散系数,并从自由体积分数、腐蚀介质粒子与缓蚀剂膜的相互作用、膜的自扩散性能等方面对缓蚀剂膜抑制腐蚀介质粒子扩散行为的微观机理进行了分析.扩散系数的计算结果表明:缓蚀剂膜能有效抑制腐蚀介质的迁移,削弱其腐蚀能力;与中性H2O分子对比,缓蚀剂膜对H3O+,Cl-和HCO-3带电离子的扩散具有更强的抑制效果;随烷基链长的增加,5种缓蚀剂膜对腐蚀粒子扩散的抑制能力呈增强趋势.综合分子动力学计算结果,5种缓蚀剂缓蚀性能随着烷基链长的增加逐渐增强,理论评价结论与实验结论相吻合.     

脂族酰基过氧化物分解动力学的研究 Ⅳ.正构酰基过氧化物在苯中分解形成的烷基苯异构体的鉴定和烷基的氢重排

关于脂族酰基过氧化物在苯中分解,形成的烷基自由基与苯反应生成烷基苯,文献中已有不少报道,而分解过程中由于烷基异构化可能形成烷基苯异构体的实验结果,则至今未见报道.我们用GC-MS法分离分析过氧化月桂酰(1)和过氧化丁酰(2)在苯中分解形成的烷基苯类化合物,都发现有少量氢原子重排产物.1在苯中分解形成的十一烷基苯的异构体为正十一烷基苯(3),2-苯基十一烷(4),3-苯基十一烷(5),4-苯基十一烷(6)和5-苯基十一烷(7);2在苯中分解形成正丙苯和异丙苯.烷基自由基在溶剂中发生自由基型氢重排,除1,5-氢迁移     

Thermal behaviour of mechanochemically synthesized nanocrystalline CuS

Thermal behaviour of mechanochemically synthesized nanocrystalline CuS particles by high-energy milling in an industrial mill has been studied. Structure properties were characterized by X-ray powder diffraction that reveals the formation of copper sulphide CuS as well as of copper sulphate CuSO₄·5H₂O. Thermal properties of the as-prepared products were studied by the differential scanning calorimetry together with X-ray inspection for detection by pass products formed. The decomposition of the as-prepared sample has been studied too. Thermal stability of the anhydrous CuSO₄ formed by the thermal decomposition is lower than the thermal stability of non-milled samples. The final product of the thermal decomposition is metallic copper instead of Cu₂O, which is stable up to 1100 °C. Differential scanning calorimetry (DSC) analysis proved that the percentage of chalcantite in the covellite mechanochemically synthesized by high-energy milling is 48-51%.     

Preparation and characterization of poly(copper 2,3,9,10,16,17,23,24-octacyanophthalocyanine)

Dark blue poly(copper 2,3,9,10,16,17,23,24-octacyanophthalocyanine) has been prepared by reacting 1,2,4,5-tetracyanobenzene with cuprous chloride in 1-methyl-2-pyrrolidone at ca. 150°C. The product has been characterized by elemental analysis, thermal analysis, infrared and UV-VIS spectroscopies. The polymer has high purity and exhibits good thermal stability in an inert atmosphere.     

Distribution and properties of catalytically active Cu2+ sites in mesoporous MCM-41 modified with Al, Zr, or W ions

The surface of pure mesoporous SiO₂ with an MCM-41 structure has been modified by introducing Al, Zr, or W ions (1 mmol/g). The original and modified materials have been loaded with Cu²⁺ ions. The distribution, properties, and thermal stability of different Cu²⁺ sites have been studied by EPR and IR spectroscopy. The resulting catalysts have been tested for activity in ethane oxidation. The modification of original MCM-41 exerts a very strong effect on the stability of isolated Cu²⁺ ions on the support surface. Among the modified supports, Al-MCM-41 affords the highest thermal stability and degree of dispersion (70–80%) of the copper-containing phase. There is no correlation between the total number of surface Cu²⁺ sites and the catalytic activity. The specific catalytic activity (per Cu²⁺ ion accessible to the reactants) depends strongly on the local structure of the sites. The isolated pentacoordinated Cu²⁺ sites stabilized by the Al-MCM-41 surface show a comparatively high activity in the sample calcined at 520°C. The heat treatment of Cu/Al-MCM-41 at 650–750°C reduces the specific activity of the catalytic sites by a factor of ～20 without sintering the copper phase, as in the case of CuHZSM-5 zeolite. The least dispersed copper phase, which is observed in the original MCM-41 and likely consists of aggregates of weakly interacting Cu²⁺ ions, exhibits the highest specific activity and thermal stability. In the case of Cu/W-MCM-41, heat treatment causes both the sintering of copper particles and a decrease in the specific activity of the surface Cu²⁺ ions.     

Thermal and structural studies of the chloro complexes of cobalt and copper with 2-amino-3-methylpyridine

The chloro complexes of 2-amino-3-methylpyridine with cobalt(II) and copper(II) have been prepared in ethanolic solution and solid compounds have been isolated. The compounds have stoichiometry ML₂Cl₂ whereM is Co²⁺ or Cu²⁺ and L is 2-amino-3-methylpyridine. Spectral and magnetic studies have been used to obtain information about the environment of the metal ion in these compounds. The compounds have tetrahedral structures. The thermal decomposition of each compound has been studied using thermogravimetry and differential thermal analysis. Thermogravimetry studies show that the cobalt complex forms an intermediate compound before the metal oxide is produced while the copper compound undergoes decomposition with loss of organic ligand and the formation of copper chloride which then decomposes to give an oxide of copper. The enthalpy of reaction for each of the processes has been calculated from the thermal analysis curves.     

Reactivity and thermal stability of oxidized copper clusters on the tantalum(V) oxide surface

Oxidized copper clusters 2–5 nm in size have been obtained by RF discharge sputtering of a copper wire in an oxygen atmosphere. Isolated CuO clusters or, at long deposition times, their agglomerates form on the support. The thermal stability of the oxidized nanoparticles in a vacuum and their reactivity toward CO in relation to the deposition time have been investigated by X-ray photoelectron spectroscopy. The asprepared clusters show low reactivity (10^?7?10^?9), but their activation by reduction and subsequent reoxidation in an oxygen medium raises their reactivity to ～10^?5. This is due to the appearance of weakly charged oxygen species on the surface. The reactivity of the CuO clusters has been compared to the reactivity of earlier studied nanosized copper oxide model objects.     

Mass spectra of SnI2

The thermal and spectral properties of the chelates of quinizarin with copper, cobalt and nickel have been investigated. The decreasing order of thermal stability for the chelates is Ni > Co > Cu. The chelates are compared with the corresponding chelates of naphthazarin. The effect on the thermal stability of the addition of a benzene ring to naphthazarin is compared with a previous study on 2,4-dinitrosoresorcinol and 2,4-dinitroso-1,3-naphthalenediol. Several unsuccessful attempts were made to prepare a zinc chelate of this ligand.     

配位聚合物{[Cu_2(nbdo)_2·(H_2O)_2]·2(H_2O)}_n的热稳定性以及荧光性能和储氢性能(英文)

合成了一种新的以柔性羧酸为配体的铜配位聚合物,考察了其热稳定性能、荧光性能及储氢能力.结果表明,配体2-硝基-苯-1,4-二(氧乙酸)表现出较好的柔韧性;该结构在温度低于541 K的环境中比较稳定,当温度高于541 K迅速发生分解并伴随着轻微的爆轰.配合物的荧光光谱与配体的相比有所蓝移.与此同时,该配合物的储氢能力随着氢气压力的增加而提高;当氢气压力为5.0 MPa时储氢能力可达0.42%.     

Synthesis, crystal structures and reactivity of copper(I) amidate complexes with aryl halides: insight into copper(I)-catalyzed Goldberg reaction

In this paper, copper(I) amidate complexes (2-3), proposed intermediates in copper-catalyzed Goldberg reaction, have been prepared and characterized by elemental analysis, IR, (1)H NMR and X-ray crystallography. Ancillary ligand bis(diphenylphosphino)ferrocene (dppf) has contributed greatly to the stability of the copper-amidate complexes due to its strong chelating ability and weak intermolecular interactions. Thermal gravimetric analyses are carried out to determine the thermal competency of complexes 2-3 as the intermediates of the high-temperature Goldberg reactions. Reaction of complexes 2 and 3 with aryl halides generates the N-arylation products 5-8, accompanied by the formation of a copper(I) complex Cu(dppf)X (X = I or Br) 4, which has been determined by LC-MS analysis. These results provide new evidence for the mechanism of copper(I)-catalyzed Goldberg reaction.     

Thermal, mechanical and electrical properties of copper powder filled low-density and linear low-density polyethylene composites

Low-density polyethylene (LDPE) and linear low-density polyethylene (LLDPE) with different copper contents were prepared by melt mixing. The copper powder particle distributions were found to be relatively uniform at both low and high copper contents. There was cluster formation of copper particles at higher Cu contents, as well as the formation of percolation paths of copper in the PE matrices. The DSC results show that Cu content has little influence on the melting temperatures of LDPE and LLDPE in these composites. From melting enthalpy results it seems as if copper particles act as nucleating agents, giving rise to increased crystallinities of the polyethylene. The thermal stability of the LDPE filled with Cu powder is better than that for the unfilled polymer. The LLDPE composites show better stability only at lower Cu contents. Generally, the composites show poorer mechanical properties (except Young's modulus) compared to the unfilled polymers. The thermal and electrical conductivities of the composites were higher than that of the pure polyethylene matrix for both the LDPE and LLDPE. From these results the percolation concentration was determined as 18.7 vol.% copper for both polymers.     

Synthesis of oleylamine capped copper nanocrystals via thermal reduction of a new precursor

The present investigation reports the novel synthesis of copper nanocrystals using thermal reduction, and their physicochemical characterization. The copper nanocrystal powder has been prepared using [bis(2-hydroxyacetophenato)copper(II)] as a precursor. The effect of oleylamine and triphenylphosphine on the particle morphology has been investigated. Transmission electron microscopy (TEM) analysis has demonstrated that the copper nanocrystals have an average diameter of about 3 nm. The as-prepared copper nanocrystals were characterized by XRD, SEM, TEM, EDX, UV–Vis and FTIR.