新法合成手性磷酸锌钠

对合成手性磷酸锌钠(NaZnPO₄·H₂O) (CZP)的新方法进行了研究,用Na₃PO₄·12H₂Oand ZnSO₄·7H₂O作为起始原料,聚乙二醇-400（PEG-400）为表面活性剂,通过一步低热固相反应得到了手性磷酸锌钠。用TG/DTG,XRD, TEM 及 SEM表征了产物。实验结果表明,Na₃PO₄·12H₂O与ZnSO₄·7H₂O的配比采用不同的p/Zn比（0.9～1.15）,在60 ℃下陈化不同的时间(2.0～8.0 h) 所得到的NaZnPO₄·H₂O,除了结晶度稍为不同之外,晶体的手性结构是一样的。对照实验的结果显示陈化温度及阴离子调控着NaZnPO₄·H₂O的对映体形态。即,若以ZnSO₄·7H₂O或Zn(NO₃)₂·6H₂O为锌源,当反应混合物在60 ^oC陈化时,生成产物的结构是空间群为 P6₁22 的第一种手性结构,当反应混合物在室温陈化时,生成产物的结构则是空间群为 P6₅22 的第二种手性结构。     

纳米-微米铁修饰的维氏体氨合成催化剂

我们以商业预还原的维氏体(Fe1-xO)氨合成催化剂为载体,采用Fe(NO)3 ·9H2O和H2C2O4·2H2O进行原位室温固相反应制备纳米铁或微米铁修饰的铁基氨合成催化剂,并通过XRD、SEM、TG-DTG、H2-TPR等进行了表征.结果表明:Fe(NO)3·9H2O和H2C2O4·2H2O室温固相反应完全生成产物Fe2(C2O4)3·5H2O,且产物分散于载体维氏体催化剂表面.通过纳米铁-微米铁的修饰,催化剂的氨合成活性有很大提高且稳定性好.催化剂活性随着Fe负载量的增加先增加后降低,负载量5％时催化活性最好,反应器出口氨浓由450℃(12.4％)、425℃(11.0％)、400℃(9.4％)分别提升至450℃(15.6％)、425℃(14.8％)、400℃(13％).通过一步简单的修饰,维氏体催化剂的氨合成活性提高约25％ ～38％.由于焙烧和还原,生成的Fe1xO或铁粒子与铁催化剂表面发生强相互作用,因此,反应过程中纳米铁或微米铁粒子能稳定存在,催化剂有较高的稳定性.     

铬酸铵钠复盐结晶的热分解

采用TG-DTG、DTA和XRD对铬酸铵钠复盐结晶(NaNH4CrO4•2H2O)的热分解过程进行研究,结果表明NaNH4CrO4•2H2O的热分解过程分为三步进行,第一步是在50～95 ℃温度范围结晶水的脱除,第二步是在100～180 ℃的温度范围铵的初步热分解,产物为铬酸钠和重铬酸铵,第三步是215～385 ℃进行的铵的完全分解.存在生成重铬酸钠与生成三氧化二铬的竞争反应.在氨不易扩散的条件下,最终分解产物为三氧化二铬、重铬酸钠和铬酸钠的混合物;在流动气氛中,400～790 ℃温度范围,NaNH4CrO4•2H2O热分解产物为重铬酸钠.与传统的铬酸钠硫酸酸化生产重铬酸钠工艺相比,该方法无副产物产生,是一清洁工艺.     

油包水型微乳中层柱状磷酸锆的制备与表征

以氧氯化锆(ZrOCl2·8H2O)和磷酸三丁酯(C4H9O)3PO为原料, 在正庚烷(C7H10)-十六烷基三甲基溴化铵(CTAB)/正丁醇(C4H9OH)-水的反向微乳体系中制备了Zr(HPO4)2·H2O, (H3O)+Zr2(PO4)3和Zr(HPO4)8·H2O三种不同结构的层柱状磷酸锆. 运用扫描电子显微镜(SEM)、透射电子显微镜(TEM)和X射线衍射仪(XRD)等仪器对产物进行了表征, 考察了不同微乳组成对磷酸锆结构及尺寸的影响. 结果表明, 微乳体系对层柱状磷酸锆的可控制合成具有广泛意义.     

·OH自由基与CH3CN反应机理及动力学

在CBS-QB3水平上研究了CH3CN 和·OH反应的势能面, 其中包括两个中间体和9个反应过渡态. 分别给出了各主要物质的稳定构型、相对能量及各反应路径的能垒. 根据计算的CBS-QB3势能面, 探讨了CH3CN+·OH反应机理. 计算结果表明, 生成产物P1(·CH2CN+H2O)的反应路径在整个反应体系中占主要地位. 运用过渡态理论对产物通道P1(·CH2CN+H2O)的速率常数k1(cm3·molecule-1·s-1)进行了计算. 预测了k1(cm3·molecule-1·s-1)在250-3000 K温度范围内的速率常数表达式为k1(250-3000 K)=2.06×10^-20T^3.045exp(-780.00/T). 通过与已有的实验值进行对比得出, 在实验所测定的250-320 K 范围内, 计算得到的k1的数值与已有的实验值比较吻合. 由初始反应物生成产物P1 (·CH2CN+H2O)只需要克服一个14.2 kJ·mol-1的能垒. 而产物·CH2CN+H2O生成后要重新回到初始反应物CH3CN+·OH, 则需要克服一个高达111.2 kJ·mol-1的能垒,这就表明一旦产物P1生成后就很难再回到初始反应物.     

硝酸镝与丙氨酸配位反应的热化学研究

采用新型的具有恒温环境的反应热量计 ,以 2mol L的HCl作溶剂 ,分别测定了 [Dy(NO3) 3·6H2 O +4Ala]和Dy(Ala) 4(NO3) 3·H2 O在 2 5℃时的溶解焓。通过设计的热化学循环得到六水硝酸镝与丙氨酸配位反应的反应焓ΔrHmθ=30 .638kJ mol,并计算出配合物Dy(Ala) 4(NO3) 3·H2 O在 2 98.1 5K时的标准生成焓ΔfHmθ=-3833.8kJ mo     

氯柱硼镁石的合成及其在20℃水中的溶解相转化动力学研究

报道了合成氯柱硼镁石的快捷方法及该复盐在20℃水中的溶解和相转化过程.结果表明:该复盐在水中呈现不同步溶解,首先溶脱掉MgCl2·6H2O,生成中间产物MgO·B2O2·4H2O,随后发生转化,最终转化产物是2MgO·3B2O2·15H2O.拟合出了溶解转化结晶动力学方程,提出了溶解转化结晶反应机制.     

层状配位聚合物犤Pb(NCS)_2(bpea)_n的合成,结构和非线性光学性质(bpea=1,2-双(4-吡啶基)乙烷)(英文)

室温下Pb(OAC)2·3H2O,KNCS,和1,2-双(4-吡啶基)乙烷在甲醇中反应生成了八员环支撑的层状配位聚合物犤Pb(NCS)2(bpea)犦n。三阶非线性Z-扫描研究表明该化合物具有非线性折射行为:其非线性吸收系数α2=1.1×10-11m·W-1,非线性折射系数n2=6.055×10-18m2·W-1。     

辣根过氧化物酶催化过氧化氢氧化隐性亮绿显色反应的研究

以隐性亮绿 (RBG)为氢供体底物 ,研究了辣根过氧化物酶 -H2 O2 -RBG显色反应体系的酶催化特性。在 p H 5.0～ 6.0的条件下反应形成的酶催化产物亮绿 (BG)于 63 0 .6nm处有最大吸收 ,该显色反应测定 H2 O2 的表观摩尔吸光系数为 5.64×1 0 4 L·mol- 1·cm- 1,线性范围为 3 .55× 1 0 - 8～ 6.0× 1 0 - 6 mol/ L,检出限为 3 .55×1 0 - 8mol/ L。方法用于雨水中痕量 H2 O2 的测定 ,结果满意     

以固体超强酸SO4^2-／ZrO2-Fe2O3催化合成醋酸异戊酯

以合成醋酸异戊酯为探针反应,筛选出制备固体超强酸SO2-4 /ZrO2- Fe2O3 (SZF -1 )的最佳工艺条件为:ZrOCl2·8H2O9. 7g, FeCl3·6H2O16. 2g, 常温陈化24h, 0. 5mol·L-1 H2SO4 (15mL·g-1 )浸泡5h, 550℃焙烧3h。以SZF 1为催化剂合成醋酸异戊酯的反应条件为:异戊醇200mmol, n(异戊醇)∶n(醋酸) =1. 0∶1. 3, SZF -1 1g(反应物总质量的3% ), 环己烷15mL, 回流反应3h, 酯化率93. 47%。催化剂连续使用6次后酯化率仍在70%以上。     

DTA-TG and XRD study on the reaction between ZrOCl2·8H2O and (NH4)2HPO4 for synthesis of ZrP2O7

In this paper, we report results of thermoanalytical investigation on the reaction between ZrOCl₂·8H₂O and (NH₄)₂HPO₄ in molar ratio 1:2. Differential thermal-thermogravimetric and X-ray diffraction analyses were performed in order to reveal the chemical transformations, which took place during heating of the individual compounds ZrOCl₂·8H₂O, (NH₄)₂HPO₄ and the mixture ZrOCl₂·8H₂O:2(NH₄)₂HPO₄. It was shown that the transformations in the mixture below 160 °C were connected with dehydration of ZrOCl₂·8H₂O and interaction between the components of the mixture, which resulted in the formation of NH₄Cl, NH₄H₂PO₄ and a mainly amorphous zirconium phase, most likely t-ZrO₂. The zirconium component subsequently reacted with ammonium dihydrophosphate (below 200 °C) or with dehydrated phosphate derivatives (above 200 °C), which in both cases yielded an amorphous product. The interaction between the components of the mixture resulting in the formation of ZrP₂O₇ was completed by its crystallisation at 610 °C. Our study indicates an alternative low-temperature approach for the synthesis of the technologically important ZrP₂O₇ material.     

Crystal Structures,Magnetic Properties and Catecholase‐Like Activities of μ‐Alkoxo‐μ‐Carboxylato Double Bridged Dinuclear and Tetranuclear Copper(II) Complexes

One μ‐alkoxo‐μ‐carboxylato bridged dinuclear copper(II) complex, [Cu₂(L¹)(μ‐C₆H₅CO₂)] ( 1 )(H₃L¹ = 1,3‐bis(salicylideneamino)‐2‐propanol)), and two μ‐alkoxo‐μ‐dicarboxylato doubly‐bridged tetranuclear copper(II) complexes, [Cu₄(L¹)₂(μ‐C₈H₁₀O₄)(DMF)₂]·H₂O ( 2 ) and [Cu₄(L²)₂(μ‐C₅H₆O₄]·2H₂O·2CH₃CN ( 3 ) (H₃L² = 1,3‐bis(5‐bromo‐salicylideneamino)‐2‐propanol)) have been prepared and characterized. The single crystal X‐ray analysis shows that the structure of complex 1 is dimeric with two adjacent copper(II) atoms bridged by μ‐alkoxo‐μ‐carboxylato ligands where the Cu···Cu distances and Cu‐O(alkoxo)‐Cu angles are 3.5 11 Å and 132.8°, respectively. Complexes 2 and 3 consist of a μ‐alkoxo‐μ‐dicarboxylato doubly‐bridged tetranuclear Cu(II) complex with mean Cu‐Cu distances and Cu‐O‐Cu angles of 3.092 Å and 104.2° for 2 and 3.486 Å and 129.9° for 3 , respectively. Magnetic measurements reveal that 1 is strong antiferromagnetically coupled with 2J =‐210 cm^?1 while 2 and 3 exhibit ferromagnetic coupling with 2J = 126 cm^?1 and 82 cm^?1 (averaged), respectively. The 2J values of 1–3 are correlated to dihedral angles and the Cu‐O‐Cu angles. Dependence of the pH at 25 °C on the reaction rate of oxidation of 3,5‐di‐tert‐butylcatechol (3,5‐DTBC) to the corresponding quinone (3,5‐DTBQ) catalyzed by 1–3 was studied. Complexes 1–3 exhibit catecholase‐like active at above pH 8 and 25 °C for oxidation of 3,5‐di‐tert‐butylcatechol.     

Bis(iminodiethylenedi­ammonium) di‐μ5‐hydrogen­phosphato‐penta­molybdate(VI) tetra­hydrate

The crystal structure of the title compound, (C₄H₁₅N₃)₂[Mo₅O₁₅(HPO₄)₂]·4H₂O, is made up of [Mo₅O₁₅(HPO₄)₂]⁴⁻ clusters, iminodiethylenediammonium cations and solvent water mol­ecules. The [Mo₅O₁₅(HPO₄)₂]⁴⁻ cluster, with approximate C₂ symmetry, can be considered as a ring formed by five distorted edge‐ and corner‐sharing MoO₆ octa­hedra, capped on both poles by a hydro­phosphate tetra­hedron. There exist N—H⋯O, O—H⋯N and C—H⋯O hydrogen bonds between the organic ammonium groups and the clusters, with inter­atomic N⋯O distances ranging from 2.675 (3) to 2.999 (3) Å, and C⋯O distances ranging from 3.139 (5) to 3.460 (5) Å.     

Characterization of Two Zincophosphates (UH‐6 and UH‐10) Synthesized using the Cobalt(III) Sarcophagine Complex as Structure‐directing Agent

The novel zincophosphates UH‐6 (sum formula |[Co(diAMHsar)]| [Zn₂(HPO₄)₃(PO₄)] · H₂O) and UH‐10 (sum formula |([Co(diAMHsar)])₂| [{Zn₂(HPO₄)₃(PO₄)}₂] · H₂O) were synthesized in hydrothermal syntheses employing the chiral sarcophagine complex [Co(diAMHsar)]⁵⁺ as the structure‐directing agent. The inorganic part of UH‐6 consists of pearl‐like chains of alternating [ZnO₄] and [PO₄] tetrahedra, which are connected to the incorporated cobalt complex via numerous hydrogen bonds. UH‐10 was synthesized under similar conditions, but at higher reaction temperatures. In consequence, the crystal structures of UH‐6 and UH‐10 are closely related, although systematic disorder in UH‐10 and the lower symmetry result in a unit cell twice as large as the corresponding unit cell of UH‐6. Interestingly, in both zincophosphates only one enantiomer of the cobalt complex is present, despite the fact that a racemic mixture of the complex salt is used for synthesis. Thermogravimetric analysis and powder X‐ray diffraction of a thermally treated sample of UH‐6 reveals a phase transformation at ca. 300 °C.     

Effects of Temperature and Anion on the Copper(II) Complexes based on 2‐(Carboxyphenyl)iminodiacetic Acid and 1,10‐Phenanthroline

Using Cu(NO₃)₂ as metal salt, [Cu₃(cpida)(phen)₂(H₂O)₅] · 3NO₃ · 2H₂O ( 1 ) and {[Cu₂(cpida)(phen)(NO₃)] · 2H₂O}_n ( 2a ) were synthesized from an identical starting mixture with 2‐(carboxyphenyl)iminodiacetic acid (H₃cpida) and 1,10‐phenanthroline (phen) at 5 °C and 25 °C, respectively. Additionally, complexes 2b – 2d , which are isostructural to 2a , were obtained using Cu(ClO₄)₂, Cu(BF₄)₂, and Cu(CF₃SO₃)₂ instead of Cu(NO₃)₂ in the temperature range 0–65 °C. 1 is characterized by a V‐shaped trinuclear Cu^II monomer, whereas 2a – 2d features a one‐dimensional (1D) Δ Cu^II chain. Abundant hydrogen bonds constructed by the nitrate anion are observed in 1 . A structural transformation study was undertaken and revealed that 1 could completely transform into 2a from the reaction solution at 25 °C and the temperature plays a crucial role in the process. Magnetic measurements revealed that 1 exhibits dominant antiferromagnetic behavior, whereas 2a presents dominant ferromagnetic behavior.     

H3OLa(SO4)2 · 3 H2O: Ein neues saures Sulfat der Selten‐Erd‐Elemente

H₃OLa(SO₄)₂ · 3 H₂O: A New Acidic Sulfate of the Rare Earth Elements Colorless single crystals of H₃OLa(SO₄)₂ · 3 H₂O have been obtained by the reaction of La₂O₃ and sulfuric acid (80% H₂SO₄) at 150 °C. In the crystal structure (monoclinic, P2₁/c, Z = 4, a = 1119.5(5), b = 693.3(2), c = 1357.4(4) pm, β = 110.94(4)°) La³⁺ is ninefold coordinated by oxygen atoms which belong to five SO₄^– ions and three H₂O molecules. One of sulfate groups acts as a bidentate ligand. Hydrogen bonding is observed with H₂O molecules as donors and acceptors. Furthermore, strong hydrogen bonds are formed between the H₃O⁺ ions and oxygen atoms of the SO₄^2– groups.     

2‐Amino‐5‐(2‐pyridyl)‐thiadiazole as Bidentate Ligand

The amino substituted bidentate chelating ligand 2‐amino‐5‐(2‐pyridyl)‐1,3,4‐thiadiazole (H₂ L ) was used to prepare 3:1‐type coordination compounds of iron(II), cobalt(II) and nickel(II). In the iron(II) perchlorate complex [Fe^II(H₂ L )₃](ClO₄)₂·0.6MeOH·0.9H₂O a 1:1 mixture of mer and fac isomers is present whereas [Fe^II(H₂ L )₃](BF₄)₂·MeOH·H₂O, [Co^II(H₂ L )₃](ClO₄)₂·2H₂O and [Ni^II(H₂ L )₃](ClO₄)₂·MeOH·H₂O feature merely mer derivatives. Moessbauer spectroscopy and variable temperature magnetic measurements revealed the [Fe^II(H₂ L )₃]²⁺ complex core to exist in the low‐spin state, whereas the [Co^II(H₂ L )₃]²⁺ complex core resides in its high‐spin state, even at very low temperatures.     

Thermal decomposition kinetics and reversible hydration study of the Li2Zn(HPO4)2·H2O

The dilithium zinc hydrogen phosphate monohydrate (Li₂Zn(HPO₄)₂·H₂O) was synthesized at the ambient temperature by using zinc acetyl acetonate monohydrate, phosphoric acid and lithium hydroxide monohydrate. The thermal stability of the Li₂Zn(HPO₄)₂·H₂O was studied by non-isothermal kinetic method (Ozawa and Kissinger) from the differential scanning calorimetric (DSC) data. The studied hydrate undergoes two endothermic thermal transformations, which the first transformation is due to the release of water molecule of crystallization and the second one is due to the release of water of constituent from HPO₄^2? anions and transforms to P₂O₇^4?. The activation energies (E_a) calculated for the dehydration step and decomposition step of the Li₂Zn(HPO₄)₂·H₂O from different methods were found to be consistent. The dehydration and rehydration processes of the synthesized compound were investigated and found that the water of crystallization can be removed and rehydrated without the disrupting the structure of the material, provided it is not heated beyond 200 °C. The dehydration and rehydration processes of the synthesized Li₂Zn(HPO₄)₂·H₂O exhibits similar property to the zeolite.     

Copper(II)‐Catalyzed Synthesis of N‐Substituted‐3‐amino‐4‐cyano‐isoquinoline‐1(2H)‐ones by the Reaction of N‐Substituted‐2‐iodobenzamides with Malononitrile

A novel Cu(OAc)₂·H₂O catalyzed coupling reaction of N‐substituted‐2‐iodobenzamides with malononitrile to afford N‐substituted‐3‐amino‐4‐cyano‐isoquinoline‐1(2H)‐ones is described. The reaction proceeded in DMSO at 90°C for 5 h in nitrogen without external ligands.