稀土固体超强酸SO_4~(2-)/TiO_2-La~(3+)催化合成尿囊素

尿囊素(1 脲基间二氮杂茂烷二酮—(2,4),allantoin)是一种两性化合物,可作为医药、化妆品、农业等化工原料中间体。通常用硝酸或过氧化氢氧化乙二醛生成乙醛酸后,再在酸催化下由乙醛酸与尿素缩合而成。但采用浓H2SO4、HNO3等作催化剂,产率偏低(<50%),选择性差,产品质量不好,同时设备腐蚀严重,污染环境。用SO2-4/MxOy型固体超强酸催化剂催化合成尿囊素[2 3],仍有产率偏低等不足之处。我们用La3+掺杂改性SO2-4/TiO2体系,合成了稀土固体超强酸催化剂SO2-4/TiO2 La3+,考察了合成尿囊素缩合反应的催化条件,在最适宜的反应条件下,催化…     

SO_4~(2-)/TiO_2固体超强酸新制备方法及其对形成邻苯二甲酸二丁酯的催化活性

建立了用钛白粉制备固体超强酸SO42-/TiO2的新方法.考察了超强酸SO42-/TiO2的制备条件对催化邻苯二甲酸酐和正丁醇酯化反应的催化活性的影响.实验表明,以合成的超强酸为催化剂,在160℃反应4h,邻苯二甲酸二丁酯的产率大于99%.     

SO42-/TiO2固体超强酸新制备方法及其对形成邻苯二甲酸二丁酯的催化活性

建立了用钛白粉制备固体超强酸SO4^2-/TiO2的新方法．考察了超强酸SO4^2-/TiO2的制备条件对催化邻苯二甲酸酐和正丁醇酯化反应的催化活性的影响．实验表明，以合成的超强酸为催化剂，在160℃反应4h，邻苯二甲酸二丁酯的产率大于99％．     

焙烧温度对纳米级SO2- 4/TiO2固体超强酸性能的影响

用锐钛型纳米TiO2制备了纳米级SO2- 4/TiO2固体超强酸,考查了焙烧温度对酸强度、比表面积、红外光谱及其催化活性的影响.结果显示该催化剂在450℃焙烧3 h,可以形成纳米级SO2-4/TiO2固体超强酸的结构.用该催化剂催化乙酸和丁醇酯化反应可使酯化率达到98.4%.     

固体超强酸SO2-4/TiO2-SnO2的制备、表征及催化合成D, L-丙交酯

采用沉淀法在不同工艺条件下制备了稀土改性的新型固体超强酸SO2-4/TiO2-SnO2催化剂, 考察了其对D, L-乳酸合成D, L-丙交酯的催化活性, 并通过Hammett指示剂法测定了催化剂的酸强度, 用FT-IR和FT-Raman技术考察了焙烧温度、硫酸浸渍液浓度和浸渍时间以及La2O3的负载量对该固体超强酸结构和性能的影响. 研究结果表明: SnO2的存在促进了金红石相TiO2的形成, 在600 ℃焙烧3 h、 3.0 mol/L H2SO4溶液浸渍12 h、 n(Ti4+): n(Sn4+): n(La3+)=1:1:0.05条件下制备的SO2-4/TiO2-SnO2的酸强度最大, 达-13.75以上, 催化合成丙交酯的产率最高(78.4%). 并且考察了催化剂用量对D, L-丙交酯粗产率的影响和催化剂重复使用的性能.     

固体超强酸SO4^2——MoO3—TiO2的制备及其催化酯化性能研究

SO4^2--MxOy型固体超强酸自问世以来一直受到人们的广泛关注,已对其进行了大量的研究。该类催化剂的酸度强度高,在烷基化、酰基化、裂解、醇脱水、异构化、酯化等反应中有很高的催化活性。最常用的氧化物基体是ZrO2和TiO2,最后的促进剂SO4^2-。也有用MoO3作促进剂的^[1-3],得到相应的超强酸催化剂。作者在SO4^2--TiO2超强酸的基础上,将MoO3和SO4^2-同时负载在TiO2基体上,得到SO4^2--MoO3-TiO2固体超强酸,以乙酸异戊酯的合成为探针反应考察了该催化剂的催化酯化活性,并与SO4^2--TiO2、MoO3-TiO2的催化酯化活性作了比较。     

SO2-4/TiO2-SiO2固体超强酸的结构及其光催化性能

自从Arata等[1]首次报道无卤素型SO2-4/MxOy固体超强酸体系以来, 对该类催化剂的研究引起了人们的广泛重视. 大量研究工作表明, 固体超强酸催化剂对丁烷异构化、苯衍生物烷基化、链烷烃裂解和乙烯二聚等诸多酸催化的反应表现出极高的反应活性[2]. 最近, 我们把SO2-4/TiO2型固体超强酸应用于有机物的光催化氧化反应, 研究发现TiO2光催化剂经H2SO4浸渍处理形成固体超强酸后, 催化剂的光催化活性大大提高, 并具有很好的反应活性、稳定性和抗湿性能[3];     

S2O2-8-/ZrO2-Al2O3固体超强酸催化剂的研制与应用

固体超强酸因其特殊的晶相结构和表面特性及高比表面积使其具有许多重要的催化特性[1],某些经特殊处理得到的金属氧化物(如ZrO2、TiO2、Fe 2O3等)负载SO24-后可以成为固体超强酸[2]..有关SO24-/ZrO2系列固体超强酸的研究和应用报道较多[3,4a,5].夏勇德等[4b,6]报道用(NH4)2S2O8浸渍无定形Zr(OH)4可制备超强酸性和催化活性比SO24-/ZrO2更强的新型固体超强酸S2O28-/ZrO2.本文在文献方法的基础上,制出新型固体超强酸S2O28-/ZrO2-Al2O3,以乙酸和正丁醇的酯化反应作探针,优选出高活性催化剂并成功地用于催化合成4种缩酮(醛)类化合物.它们经纯化处理后均可作为食用香料.     

2,6-二(5-烷基水杨基)-4-烷基苯酚的合成

以自制的正构长链烷基酚为原料与多聚甲醛在碱性催化剂下进行羟甲基化反应,生成2,6-二羟甲基-4-烷基苯酚,再与另两分子烷基酚在固体超强酸催化下进行缩合反应生成2,6-二(5-烷基水杨基)-4-烷基苯酚,用核磁共振氢谱和碳谱、红外光谱和元素分析对产物进行了结构鉴定,探讨了催化剂、反应物料配比、反应时间等条件对产物产率的影响.另外根据上述反应路线,以工业品壬基酚和多聚甲醛为原料,经羟甲基化反应、缩合反应合成了2,6-二(5-壬基水杨基)-4-壬基苯酚.上述两种结果表明,选用SO24-/SnO2固体超强酸作催化剂,2,6-二羟甲基-4-烷基苯酚和烷基酚的配比为1:2,140℃反应2h,产率达到95%.     

焙烧温度对纳米级SO_4~(2-)/TiO_2固体超强酸性能的影响

用锐钛型纳米TiO2制备了纳米级SO42-/TiO2固体超强酸,考查了焙烧温度对酸强度、比表面积、红外光谱及其催化活性的影响.结果显示该催化剂在450℃焙烧3 h,可以形成纳米级SO42-/TiO2固体超强酸的结构.用该催化剂催化乙酸和丁醇酯化反应可使酯化率达到98.4%.     

Sc2MgGa2 and Y2MgGa2

Scandium magnesium gallide, Sc₂MgGa₂, and yttrium magnesium gallide, Y₂MgGa₂, were synthesized from the corresponding elements by heating under an argon atmosphere in an induction furnace. These intermetallic compounds crystallize in the tetragonal Mo₂FeB₂‐type structure. All three crystallographically unique atoms occupy special positions and the site symmetries of (Sc/Y, Ga) and Mg are m2m and 4/m, respectively. The coordinations around Sc/Y, Mg and Ga are pentagonal (Sc/Y), tetragonal (Mg) and triangular (Ga) prisms, with four (Mg) or three (Ga) additional capping atoms leading to the coordination numbers [10], [8+4] and [6+3], respectively. The crystal structure of Sc₂MgGa₂ was determined from single‐crystal diffraction intensities and the isostructural Y₂MgGa₂ was identified from powder diffraction data.     

Electrochemical study of (NEt4)2Cl2FeS2MoS2 and (NEt4)2Cl2FeS2MoS2FeCl2

Summary The ability of [MoS₄]^2–, anions to be used as ligands for transition metal ions has been widely demonstrated, especially with Fe²⁺. The present study has been restricted to linear complexes such as (NEt₄)₂ [Cl₂FeS₂MoS₂] and (NEt₄)₂[Cl₂FeS₂MoS₂FeCl₂]. Their electrochemical properties are described: upon electrochemical reduction, these compounds yield MoS₂, as a black precipitate, and an iron complex in solution, assumed to be [SFeCl₂]^2–. The electrochemical reduction goes through two electron transfers, coupled with the breakdown of the molecular skeleton: a DISPl and an ECE mechanism. Depending on the solvent, the following equilibrium may be observed: [Cl₄Fe₂MoS₄]^2–[Cl₂FeMoS₄]^2–+FeCl₂. The equilibrium constant, K_D, was evaluated by differential pulse polarography. K_D is tightly related to the donor number of the solvent.     

The alkali hypophosphites KH2PO2, RbH2PO2 and CsH2PO2

The structures of the hypophosphites KH₂PO₂ (potassium hypophosphite), RbH₂PO₂ (rubidium hypophosphite) and CsH₂PO₂ (caesium hypophosphite) have been determined by single‐crystal X‐ray diffraction. The structures consist of layers of alkali cations and hypophosphite anions, with the latter bridging four cations within the same layer. The Rb and Cs hypophosphites are isomorphous.     

Zur Kenntnis der Dialkalimetalldichalkogenide β-Na2S2, K2S2, α-Rb2S2, β-Rb2S2, K2Se2, Rb2Se2, α-K2Te2, β-K2Te2 und Rb2Te2

On Dialkali Metal Dichalcogenides β-Na₂S₂, K₂S₂, α-Rb₂S₂, β-Rb₂S₂, K₂Se₂, Rb₂Se₂, α-K₂Te₂, β-K₂Te₂ and Rb₂Te₂ The first presentation of pure samples of α- and β-Rb₂S₂, α- and β-K₂Te₂, and Rb₂Te₂ is described. Using single crystals of K₂S₂ and K₂Se₂, received by ammonothermal synthesis, the structure of the Na₂O₂ type and by using single crystals of β-Na₂S₂ and β-K₂Te₂ the Li₂O₂ type structure will be refined. By combined investigations with temperature-dependent Guinier-, neutron diffraction-, thermal analysis, and Raman-spectroscopy the nature of the monotropic phase transition from the Na₂O₂ type to the Li₂O₂ type will be explained by means of the examples α-/β-Na₂S₂ and α-/β-K₂Te₂. A further case of dimorphic condition as well as the monotropic phase transition of α- and β-Rb₂S₂ is presented. The existing areas of the structure fields of the dialkali metal dichalcogenides are limited by the model of the polar covalence.     

Formal [(2+2)+2] and [(2+2)+(2+2)] nonconjugated dienediyne cascade cycloadditions

[reaction: see text] Fluoranthene 2 and heptacycle 3 are easily accessible from the reaction of diyne 1 and norbornadiene (NBD) in the presence of the rhodium catalyst. The unusual [(2+2)+(2+2)] adduct 3 was confirmed by the X-ray crystal structure analysis.     

Crystal Structures of [Bu2Sn(O2PPh2)2], [Ph2Sn(O2PPh2)2], and [PhClSn(O2PPh2)OMe]2. Raman Spectra of [Ph2Sn(O2PPh2)2] and [PhClSn(O2PPh2)OMe]2

[(n‐Bu)₂Sn(O₂PPh₂)₂] ( 1 ), and [Ph₂Sn(O₂PPh₂)₂] ( 2 ) have been synthesized by the reactions of R₂SnCl₂ (R=n‐Bu, Ph) with HO₂PPh₂ in Methanol. From the reaction of Ph₂SnCl₂ with diphenylphosphinic acid a third product [PhClSn(O₂PPh₂)OMe]₂ ( 3 ) could be isolated. X‐ray diffraction studies show 1 to crystallize in the monoclinic space group P2₁/c with a = 1303.7(1) pm, b = 2286.9(2) pm, c = 1063.1(1) pm, β = 94.383(6)°, and Z = 4. 2 crystallizes triclinic in the space group , the cell parameters being a = 1293.2(2) pm, b = 1478.5(4) pm, c = 1507.2(3) pm, α = 98.86(3)°, β = 109.63(2)°, γ = 114.88(2)°, and Z = 2. Both compounds form arrays of eight‐membered rings (SnOPO)₂ linked at the tin atoms to form chains of infinite length. The dimer 3 consists of a like ring, in which the tin atoms are bridged by methoxo groups. It crystallizes triclinic in space group with a = 946.4(1) pm, b = 963.7(1) pm, c = 1174.2(1) pm, α = 82.495(6)°, β = 66.451(6)°, γ = 74.922(6)°, and Z = 1 for the dimer. The Raman spectra of 2 and 3 are given and discussed.     

Die Photoionenspektren von SCl2, S2Cl2 und S2Br2

Photoionization Mass Spectra of SCl₂, S₂Cl₂, and S₂Br₂ Photoionization mass spectra of SCl₂, S₂Cl₂, and S₂Br₂ have been measured. Heats of formation, bond energies, and ionization potentials of fragments have been calculated from appearance potentials.