硼氢化钠还原潜手性酮反应机理的量子化学研究

用从头计算方法对硼氢化钠不对称还原对甲基环己酮的机理进行了研究. 探讨了四元环和六元环机理, 其中每种机理有三种途径, 主要的途径是经过过渡态的两步反应途径. 计算结果表明, 无溶剂参与反应的四元环过渡态机理虽然能解释其还原历程, 但计算所得的对映体组成与文献值相差很大. 而对质子性溶剂异丙醇参与的六元环机理的研究发现反应产物的对映体组成的计算结果与文献实验值吻合较好. 这表明该反应主要经历六元环过渡态的两步反应历程.     

(4,5-二氮杂-9-亚芴基)碳60中的分子轨道相互作用及其电子光谱和二阶非线性光学性质

在ZINDO方法基础上,按完全态求和(SOS)公式编制了计算分子二阶非线性光学系数β的程序.研究了(4,5-二氮杂-9-亚芴基)碳60中的分子轨道相互作用,计算了该分子的电子光谱和二阶非线性光学系数,前者与实验结果较好地吻合,后者属于理论预测性质.     

9-羟基-芴-9-羧酸甲酯的晶体结构

9-羟基-芴-9-羧酸衍生物是一种植物生长调节剂。它能引起植物形态变化,还能增强苯氧烷基羧酸类防落素的作用,已广泛应用于名贵花卉和果树等。然而,芴和9-羟基-芴-9-羧酸衍生物的晶体结构均未见报道。本文报告了9-羟基-芴-9-羧酸甲酯的晶体结构。     

4,5-二氮芴-9-酮及其衍生物的研究进展

介绍了4,5-二氮芴-9-酮及其衍生物的合成方法及其在新型催化剂和光电材料等方面的研究进展。标题化合物及其衍生物是一类结构、性质特殊的化合物,提示其更广泛的性质和应用还有待人们更深入研究。     

10-苄基吖啶酮的合成及其与硼氢化钠还原反应研究

合成了一系列的10-苄基吖啶酮类化合物, 并探讨了一种用硼氢化钠氢化还原吖啶酮制备10-苄基-9,10-二氢吖啶的简便方法. 吖啶酮1与氯化苄及其衍生物2在氢化钠/N,N-二甲基甲酰胺/碘化钾中反应高产率生成10-苄基吖啶酮类化合物3; 3经硼氢化钠氢化还原生成10-苄基-9,10-二氢吖啶类化合物4, 产率88%～96%. 反应中没有得到预期的产物10-苄基-9,10-二氢吖啶醇类化合物4’, 其反应机理可能是3首先被硼氢化钠还原成醇中间体4’, 4’在硼氢化钠存在下不稳定, 迅速地被进一步还原成4.     

9-氯-9-硼芴与NaBH4反应的理论研究

采用密度泛函理论研究了9-氯-9-硼芴与NaBH₄反应的机理, 优化得到了10个中间体和12个过渡态, 并确定了可能的反应通道. 计算结果表明: 主反应通道包含了6个中间体和5个过渡态, 决速步活化能为80.35 kJ•mol^－1, 9-硼芴并非反应势能面上最稳定的中间体. 解释了实验上不能成功分离出稳定中间体9-硼芴的原因.     

9-氯-9-硼芴与NaBH4反应的理论研究

采用密度泛函理论研究了9-氯-9-硼芴与NaBH₄反应的机理, 优化得到了10个中间体和12个过渡态, 并确定了可能的反应通道. 计算结果表明: 主反应通道包含了6个中间体和5个过渡态, 决速步活化能为80.35 kJ•mol^－1, 9-硼芴并非反应势能面上最稳定的中间体. 解释了实验上不能成功分离出稳定中间体9-硼芴的原因.     

鲁米诺-H2O2体系化学发光对邻氯代苯亚甲基丙二腈和丙二腈的研究

基于鲁米诺-过氧化氢体系对邻氯代苯亚甲基丙二腈(CS)和丙二腈的化学发光的检测,考察了其反应动力学曲线,详细研究了pH值,鲁米诺浓度,过氧化氢浓度,本底信号的稳定性对化学发光强度的影响.CS的检测线性范围为10-2～10-5mol/L,绝对检测限为1.1ng(S/N=3/1).丙二腈的检测线性范围为10-3～10-6mol/L,绝对检测限为0.5ng(S/N=3/1).建立了鲁米诺-过氧化氢体系对液相化学发光对CS和丙二腈的分析方法,对CS的沙土样品进行测定,结果令人满意.     

烟酰胺辅酶模型对N－芳基芴亚胺的酸催化还原反应的研究

报道了５种Ｎ－芳基芴亚胺在酸性条件下被烟酰胺辅酶模型（Ｈａｎｔｚｓｃｈ酯，ＢＮＡＨ）还原的反应。结果表明：亚胺的结构、酸的强度以及溶剂的不同均会影响亚胺的还原效率，本文结合反应的结构效应、溶剂效应和同位素效应，对其可能的酸催化氢负离子转移机理进行了讨论。     

B-[9,9-双(4-甲基苯基)-9H-芴-2-基]硼酸的合成工艺优化

以2-溴-9-芴酮为原料,经亲核加成、取代、氧化还原、氧化反应合成B-[9,9-双(4-甲基苯基)-9H-芴-2-基]硼酸,其结构经¹H NMR确证。采用响应面法重点对氧化还原步骤进行优化。确定较优合成条件为：反应时间5.4 h,催化剂用量为0.4 eq.,反应温度为108 ℃,目标产物收率92.15%,相对误差0.54%。     

用NaBH4还原3-(3,4-二苄氧基苯基)-2-羟基丙烯酸甲酯

用NaBH4还原3-(3,4-二苄氧基苯基)-2-羟基丙烯酸甲酯得到3-(3,4-二苄氧基苯基)-乳酸甲酯和3,4-二苄氧基苯基-1,2-丙二醇(1)。1的结构经1HNMR,13CNMR和MS确定。     

Enantioselective Reduction of Achiral Ketones with NaBH_4/I_2 Catalyzed by (S)-Ferrocenyl Amino Alcohols

In recent years much attention has been devoted to the enantioselective synthesis of optically active alcohols which are important starting materials for many biologically active compounds1. Since Corey and co-workers found the chiral oxazaborolidine catalyzed reduction (CBS reduction) of prochiral ketones, the method for the generation of chiral secondary alcohols has become one of the most attractive research fields2, 3. But borane and its complexes such as borane-THF or borane-dimethyl …     

Hydrogenolysis of Lignin Catalyzed by NaBH4/I2

从麦草碱法制浆黑液中提取木质素,精制后,以苯乙酮为木质素的模型化合物,对催化剂组成及溶剂进行了考察.在此基础上,以NaBH4/I2为催化剂,无水乙醇为溶剂,对木质素进行加氢还原裂解反应研究.考察了温度和时间对木质素催化加氢效果的影响,采用红外光谱（FTIR）、元素分析及凝胶渗透色谱分析（GPC）,表征木质素反应前后结构的变化.凝胶渗透色谱分析表明,加氢还原后木质素的分子量明显降低.采用自动电位滴定法测定反应前后木质素中总羟基含量,反应后木质素中总羟基含量为10.19%.得到了NaBH4/I2催化木质素加氢还原反应的最优条件：以1,2-二氯乙烷和乙醇（2∶1,v/v）作溶剂,m（NaBH4）∶m（I2）=1∶1,温度175℃,反应时间15 h.     

金属离子对苯甲酰丙酮选择性还原的影响

以NaBH4为还原剂,研究了金属离子对苯甲酰丙酮选择性还原的影响。结果发现,添加Cd^2＋主要得到3-羰基被还原的产物,而单独使用硼氢化钠还原时却得到两个羰基同时被还原的产物。     

Multi‐shaped Amorphous Alloy Ni‐B: Ultrasonically Aided Complexing‐reduction Preparation,Catalytic Ability for NaBH4 Hydrolysis Yielding H2 Gas

The multi‐shaped amorphous alloy (Ni‐B) powders were prepared by complexing reduction route using sodium borohydride (NaBH₄) as reductant with assistance of ultrasonic wave. The selected complexants, i.e. water, ammonia, salicylic acid, and ethylene diamine tetraacetic acid (EDTA) possess sequentially escalating complexation ability. The chemical composition and shapes of the product samples obtained under different conditions were characterized by X‐ray powder differaction, selected area electron diffraction, and transmission electron microscope. The influence of reaction conditions such as the types of Ni‐B, temperatures, NaBH₄ concentrations, and sodium hydroxide (NaOH) content on the hydrogen generation rate of hydrolysis of NaBH₄ solution were investigated in detail. The results show that the as‐prepared Ni‐B powders all belong to amorphous alloy with variable element contents, and the Ni‐B sample prepared from EDTA complexation, possessing the best fineness and dispersity, has the strongest catalytic activity. The mean apparent activation energy of the hydrolysis reaction is 64.90 kJ · mol^–1. The NaBH₄ concentration has little impact on hydrogen generation rate, implying that the catalytic hydrolysis of NaBH₄ solution should be the pseudo zero‐order reaction. Keeping the NaOH content at below 5 % could inhibit the hydrolysis of NaBH₄ solution, but the NaOH contents from 10 % to 15 % will significantly promote the hydrolysis rate of NaBH₄. The hydrolysis reaction mechanisms, especially the effect of NaOH content on the hydrolysis reaction were also analyzed.     

Metal–Organic Framework (MOF)-Derived Electron-Transfer Enhanced Homogeneous PdO-Rich Co3O4 as a Highly Efficient Bifunctional Catalyst for Sodium Borohydride Hydrolysis and 4-Nitrophenol Reduction

Developing a bifunctional catalyst with low cost and high catalytic performance in NaBH₄ hydrolysis for H₂ generation and selective reduction of nitroaromatics will make a significant impact in the field of sustainable energy and water purification. Herein, a low-loading homogeneously dispersed Pd oxide-rich Co₃O₄ polyhedral catalyst (PdO-Co₃O₄) with concave structure is reported by using a metal–organic framework (MOF)-templated synthesis method. The results show that the PdO-Co₃O₄ catalyst has an exceptional turnover frequency (3325.6 mol_H2 min⁻¹ mol_Pd⁻¹), low activation energy (43.2 kJ mol⁻¹), and reasonable reusability in catalytic H₂ generation from NaBH₄ hydrolysis. Moreover, the optimized catalyst also shows excellent catalytic performance in the NaBH₄ selective reduction of 4-nitrophenol to 4-aminiphenol with a high first-order reaction rate of approximately 1.31 min⁻¹. These excellent catalytic properties are mainly ascribed to the porous concave structure, monodispersed Pd oxide, as well as the unique synergy between PdO and Co₃O₄ species, which result in a large specific surface area, high conductivity, and fast solute transport and gas emissions.     

Catalytic Enantioselective Reduction of Prochiral Ketones with Chiral Ferrocenyl Amino Alcohols

The asymmetric reduction of prochiral ketones was catalyzed by a class of recoverable and highly stable chiral ferrocenyl amino alcohols derived from natural amino acids to yield optically active secondary alcohols in high chemical yields and moderate to good enantiomeric excesses.     

Oxygen Reduction on Amalgamated Platinum Electrodes Coated with Monolayers of Cetyl Alcohol and Stearic Acid

Oxygen reduction on an amalgamated platinum electrode with a monolayer of cetyl alcohol or stearic acid is studied. It is shown that the process proceeds inside the monolayer, most probably, at a certain distance from the metal; an electron is transferred to the reagent by the superexchange mechanism. The process characteristics depend on competition between several factors: the electron transfer distance, the potential drop between the electrode and the reagent in a given site in the monolayer, and the hydrogen ion concentration distribution across the film. The penetration of H⁺ inside the film appears to be responsive to the monolayer structure.     

Hierarchical ZnCo2O4@NiCo2O4 Core–Sheath Nanowires: Bifunctionality towards High‐Performance Supercapacitors and the Oxygen‐Reduction Reaction

Increasing energy demands and worsening environmental issues have stimulated intense research on alternative energy storage and conversion systems including supercapacitors and fuel cells. Here, a rationally designed hierarchical structure of ZnCo₂O₄@NiCo₂O₄ core–sheath nanowires synthesized through facile electrospinning combined with a simple co‐precipitation method is proposed. The obtained core–sheath nanostructures consisting of mesoporous ZnCo₂O₄ nanowires as the core and uniformly distributed ultrathin NiCo₂O₄ nanosheets as the sheath, exhibit excellent electrochemical activity as bifunctional materials for supercapacitor electrodes and oxygen reduction reaction (ORR) catalysts. Compared with the single component of either ZnCo₂O₄ nanowires or NiCo₂O₄ nanosheets, the hierarchical ZnCo₂O₄@NiCo₂O₄ core–sheath nanowires demonstrate higher specific capacitance of 1476 F g^?1 (1 A g^?1) and better rate capability of 942 F g^?1 (20 A g^?1), while maintaining 98.9 % capacity after 2000 cycles at 10 A g^?1. Meanwhile, the ZnCo₂O₄@NiCo₂O₄ core–sheath nanowires reveal comparable catalytic activity but superior stability and methanol tolerance over Pt/C as ORR catalyst. The impressive performance may originate from the unique hierarchical core–sheath structures that greatly facilitate enhanced reactivity, and faster ion and electron transfer.