Impact of Reaction Conditions on the Structures of Nickel(II) Complexes Based on 3‐(4‐Carboxyphenyl)propionic Acid

Two new nickel(II) complexes, [Ni(4, 4′‐bpy)(H₂O)₄]_n · n(cpp) · 0.5nH₂O ( 1 ) and [Ni(cpp)(4, 4′‐bpy)(H₂O)₂]_n ( 2 ) [4, 4′‐bpy = 4, 4′‐bipyridine, H₂cpp = 3‐(4‐carboxyphenyl)propionic acid] were synthesized and characterized by single‐crystal X‐ray diffraction, elemental analysis, IR spectroscopy, and thermal analysis. In complex 1 , Ni^II ions are bridged by 4, 4′‐bpy into 1D chains, and cpp ligands are not involved in the coordination, whereas in complex 2 , cpp ligands adopt a bis(monodentate) mode and link Ni^II ions into 2D (4, 4) grids with the help of 4, 4′‐bpy ligands. Triple interpenetration occurs, which results in the formation of a complicated 3D network. The difference in the structures of the two complexes can be attributed to the different reaction temperatures and bases.     

Ferrocene and Ferricenium Ion as Versatile Photometric Titrants of H2O2 and D-Glucose in the Presence of Peroxidase and Glucose Oxidase. A Ferrocene-Peroxidase Stairway #

Abstract

Hydrogen peroxide can routinely be determined in the presence of ferrocene (FcH) and horseradish peroxidase by monitoring at 617 nm the enzymatically produced ferricenium dye. In contrast, D-glucose can be assayed by following the fading of the ferricenium dye FcH⁺PF₆ ^? in the presence of glucose oxidase. The change in absorbance in both cases corresponds to the amount of analyte. viz. H₂O₂ or D-glucose, in solution. The routine is very simple, invariant to the concentrations of both ferrocenes/ferricenium salt and enzyme and allows numerous “one pot” measuremeats with the detection limit of 10^?4 M for both the analytes. It takes 2–4 and 5–10 min to accomplish one analysis of H₂O₂ and D-glucose in the presence of peroxidase and glucose oxidase, respectively.

     

烷基环己烷夺氢反应类的动力学研究

应用反应类过渡态理论(RC-TST)研究了氢自由基抽取烷基环己烷氢的反应类,给出了该类反应的动力学参数.通过研究该反应类中的14个代表反应,分析得到了RC-TST方法所需要的各种参数,建立了该类反应的线性能量关系式(LER).应用RC-TST/LER方法计算得到速率常数与TST/Eckart方法计算结果吻合很好,分析表明RC-TST/LER方法对于准确预测夺氢反应类的速率常数十分有效,可以节约大量计算成本.     

丙酮肟氧化偶联合成2,3-二甲基-2,3-二硝基丁烷反应的研究

以丙酮肟为原料,在改性TS-1(钛硅分子筛)催化剂催化下,可用H2O2氧化偶联合成2,3-二甲基-2,3-二硝基丁烷(DMNB).在此基础上以丙酮为原料,在改性TS-1催化剂催化下,一锅法进行丙酮氨肟化和氧化偶联反应可制备收率43.2%的DMNB.该方法简便易操作,操作安全.产物结构经1H NMR,13C NMR表征.     

Nature of the Ga-Ga bonding in Na2[Arx*GaGaArx*]（Arx*=C6H3 -2,6-（C6H5）2）:Electron localization function analysis

The nature of the Ga-Ga bonding in Na2[Arx*GaGaArx*](Arx* = C6H3-2,6-(C6H5)2) has been investigated and compared with that of in H2[Arx*GaGaArx*] using electron localization function(ELF) and orbital analysis.The calculation results show that in Na2[Arx*GaGaArx*],the Ga-Ga interaction is a non-classical triple bond,the heart of Na2[Arx*GaGaArx*] is the Ga2Na2 cluster rather than a simple Ga-Ga bond,and the contribution of the sodium atoms to the short Ga-Ga bond length is considerable.As the two sodium atoms are substituted by two hydrogen atoms,the Ga-Ga bond is replaced by two 3-center,2-electron(3c-2e) Ga-H-Ga covalent bridged bonding.     

半导体光解水制氢研究:现状、挑战及展望

通过半导体光催化分解水反应实现太阳能向清洁能源氢能的转化,是解决人类面临的能源和环境危机的终极途径之一。该过程的关键是开发宽光谱响应、高效的光催化剂,到目前为止,调控能带结构、制备活性晶面、构建异质结构、负载助催化剂等诸多方法被广泛应用于扩展半导体材料的吸光范围和提高其光催化活性。本文介绍了半导体光解水制氢的基本原理,并综述了该领域的研究进展,重点关注提高半导体光催化活性的方法及其所面临的挑战和瓶颈问题,并结合相关课题组的研究工作提出可能的应对策略。     

硼的添加对Ti0.26Zr0.07V0.24Mn0.1Ni0.33贮氢合金结构和电化学性能的影响

Ti_0.26Zr_0.07V_0.24Mn_0.1Ni_0.33Bx(x=0~0.10)系列合金均有V基固溶体相和C14型Laves相两相组成。添加B可提高Ti_0.26Zr_0.07V_0.24 Mn_0.1Ni_0.33合金的放电容量, Ti_0.26Zr_0.07V_0.24Mn_0.1Ni_0.33B0.1合金电极在60 mA·g^-1电流放电时的放电容量达到476.7 mAh·g^-1.B的添加不同程度地降低了合金的高倍率放电性能, 使合金电极表面上电化学反应的电荷转移电阻(R_ct)显着增加, 交换电流密度(I₀)显着降低。添加B可显着改善Ti_0.26Zr_0.07V_0.24Mn_0.1Ni_0.33合金电极的高温放电性能, Ti_0.26Zr_0.07V_0.24Mn_0.1Ni_0.33B_0.025合金电极在343 K高温下其放电容量达到525.6 mAh·g^-1.     

多孔碳负载镍纳米颗粒的制备及催化氨硼烷水解制氢

合成了蜂窝状的分级多孔碳,并以多孔碳为载体通过浸渍-化学还原法制备碳载镍(Ni/C)作为催化氨硼烷水解制氢的催化剂。采用XRD、BET、SEM、Raman、TEM等手段对样品进行了表征并研究了Ni/C室温催化性能。结果显示,多孔碳比表面积高达737 m²·g^-1,具有部分石墨化结构;负载的非晶态镍纳米颗粒平均粒径约为10 nm,均匀分布在碳基材。碳载镍对氨硼烷水解反应具有良好的催化活性,镍负载量为30wt%时催化性能最佳,298 K温度下放氢速率达到1 304.67 mL·min^-1·g^-1,活化能为29.1 kJ·mol^-1,并且具备一定的催化稳定性,表明Ni/C可作为一种廉价高效的催化剂应用于催化氨硼烷水解制氢。     

十三氟辛基修饰的疏水有机-无机杂化二氧化硅膜孔结构、氢气分离及水热稳定性

采用1,2-双（三乙氧基硅基）乙烷（BTESE）和十三氟辛基三乙氧基硅烷（PFOTES）为前驱体,在酸性条件下通过溶胶-凝胶法制备了十三氟辛基修饰的有机-无机杂化SiO₂膜材料。利用接触角测量、红外光谱、动态光散射和N₂吸附等测试技术分别对膜材料的疏水性、溶胶粒径和孔结构进行表征,并深入研究有支撑膜材料的氢气渗透、分离性能以及长期水热稳定性。结果表明,十三氟辛基修饰后的膜材料由亲水性变成了疏水性,当n_PFOTES/n_BTESE=0.6时膜材料对水的接触角达到（110.4±0.4）°,膜材料还保持微孔结构,孔径分布在0.5~0.8nm。氢气在修饰后的膜材料中的输运遵循微孔扩散机理,在300℃时,氢气的渗透率达到8.5×10^-7mol·m^-2·s^-1·Pa^-1,H₂/CO₂,H₂/CO和H₂/SF₆的理想分离系数分别为5.49,5.90和18.36,均高于相应的Knudsen扩散分离因子。在250℃且水蒸气物质的量分数为5%水热环境下陈化250h,氢气渗透率和H₂/CO₂的理想分离系数基本保持不变,膜材料具有良好的水热稳定性。