CO加氢合成C2含氧化合物Rh-Sm-V-Li/SiO2催化剂的研究

使用加压下的CO加氢反应和程序升温还原(TPR),吸附氢的程序升温脱附(H2-TPD),以及H2和CO吸附等技术,研究了Rh-Sm-V-Li/SiO2催化剂上Sm,V和Li促进剂对合成二碳含氧化合物的促进效应.结果表明,Sm和V加入到Rh/SiO2中使催化剂的活性和生成二碳含氧化合物的选择性显著提高,催化剂上的Sm3+不易被还原,Sm的加入起着提高Rh分散度的作用,使催化剂上H2和CO吸附量提高,并促进乙酸和乙醛的生成;催化剂上的高价钒离子容易还原成低价钒离子,并迁移覆盖金属Rh的表面,使催化剂上H2和CO吸附量降低.低价钒具有良好的贮氢能力,使催化剂的加氢能力显著提高,促进乙醇的生成.     

锂助剂对Rh-Mn/SiO2催化CO加氢制碳二含氧化合物性能的影响

 采用 CO 加氢反应、静态化学吸附、程序升温还原、CO 程序升温脱附和程序升温表面反应等技术研究了助剂 Li 对 Rh-Mn/SiO2 催化剂上 CO 加氢合成碳二含氧化合物性能的影响. 结果表明, Li 的加入及其负载量的增加抑制了烃类, 特别是 CH4 的生成, 而对碳二及碳二以上烃类的选择性影响较小. Li 的加入还提高了碳二含氧化合物的选择性, 主要是乙酸的选择性, 但同时降低了 Rh 基催化剂的 CO 加氢活性. 表征结果表明, Li 的加入既降低了催化剂解离 CO 的能力, 又减少了催化剂上 CO 解离活性位的数量, 从而降低了 Rh 基催化剂上 CO 加氢的速控步骤——CO 解离反应的速率. Li 负载量对 Rh-Mn/SiO2 催化剂上 H2 和 CO 的化学吸附量影响较小, 这表明并非所有的 Li 都和 Rh 发生了相互作用, 而是有相当一部分 Li 只是分散在载体 SiO2 上, 并没有与 Rh 发生接触.     

碳纳米管对Rh-Ce-Mn/SiO2催化剂催化CO加氢合成含氧化合物性能的影响

 制备了碳纳米管(CNTs)促进的Rh-Ce-Mn/SiO2催化剂,采用X射线光电子能谱、程序升温还原、 N2物理吸附、 X射线衍射以及吸附H2或CO的程序升温脱附对催化剂进行了表征,并考察了催化剂对CO加氢合成含氧化合物的催化性能. 结果表明, CNTs的添加促进了铑的分散,铑及助剂在载体表面发生富集; 活性组分铑与助剂及载体间的相互作用和催化剂样品的还原性能发生了改变; 在铑基催化剂中加入CNTs后,强吸附的H2和CO的量明显增大. CNTs促进的铑基催化剂的CO加氢活性明显提高,当CNTs添加量为10%时,一定条件下催化剂上含氧化合物的时空收率可达336.2 g/(kg·h).     

单分散SiO2的焙烧温度对Rh基催化剂上CO加氢反应性能的影响

在比较了分别以商业SiO2和采用Sto?ber法制备的单分散SiO2为载体的Rh-Mn-Li/SiO2催化剂催化CO加氢反应性能的基础上,进一步调变了Stober法制备SiO2时的焙烧温度,并考察了其对Rh-Mn-Li/SiO2催化CO加氢性能的影响.利用N2吸附-脱附、傅里叶变换红外(FTIR)光谱、H2程序升温还原(H2-TPR)、程序升温表面反应(TPSR)等方法对载体及催化剂的物理化学性能进行了表征.结果表明:不同温度焙烧的载体表面具有不同的Si―OH数量,从而影响金属的分散状态及Rh和Mn之间的相互作用.载体表面较多的羟基有利于Rh的分散和CO的吸附,从而增强催化剂的反应活性.载体表面适当数量的羟基能够得到适中的Rh与Mn之间的相互作用,使催化剂具有合适的CO解离能力,有利于CHx的CO插入反应,从而提高了C2含氧化合物的选择性.     

Rh／SiO2催化剂上甲烷部分氧化制合成气反应

 利用程序升温脱附、程序升温还原、程序升温表面反应、程序升温反应和化学捕获反应等手段，对Rh／SiO2催化剂上甲烷部分氧化制合成气反应进行了研究．结果表明，Rh／SiO2催化剂上甲烷部分氧化制合成气机理属于热解－氧化反应机理．甲烷首先在催化剂上发生解离吸附，产生具有不同H／C比的化学吸附物种CHx（x＝1～3）．其中，具有较高H／C比的CHx可能是甲烷部分氧化反应的活性物种，而具有较低H／C比的CHx可能是催化剂上积碳并导致催化剂失活的来源．活性物种CHx在活性氧物种的作用下，生成含氧中间体物种CHxO或继续脱氢．含氧中间体物种进一步分解，即生成CO和H2；CO2也可由CHx或CHxO物种进一步氧 化生成．     

Rh基催化剂上CO加氢制C2含氧化合物的红外光谱研究

 用红外光谱法考察了Rh-Mn-Li-Ti/SiO2催化剂在CO加氢反应过程中表面吸附物种随压力、温度和H2/CO比的改变而变化的规律. 结果表明,高压有利于提高催化剂表面吸附的CO浓度和活性,高温有利于CO解离; 而高温、高压条件不但促进了CO吸附,而且提高并平衡了CO的解离和插入之间的相对活性,促进了C2含氧化合物的生成. H2/CO比的增大有利于CO在催化剂表面的吸附,从而促进了CO插入,尤其是CO的解离和加氢活性,但是过高的H2/CO比将导致过高的CO解离和加氢活性,引起CO插入活性的削弱而最终导致C2含氧化合物生成活性的下降. 同时,考察了助剂(Mn, Li和Ti)对Rh基催化剂表面吸附物种的影响. 结果表明,助剂的加入可提高C2含氧化合物的生成活性.     

Rh-Mn-Li/SiO2催化剂的吸附量热和红外研究

通过在最优Rh含量基础上对金属配比的再优化,成功地改进了Rh-Mn-Li/SiO2催化剂的CO加氢性能;并采用微量吸附量热和红外等表征手段,考察了助剂Mn和Li促进作用的本质.结果表明:助剂Mn和Li的添加,使孪式和线式吸附CO的碳氧键强度增加,并同时削弱了桥式吸附CO的碳氧键或者使其转化为更易于解离的倾斜式CO吸附物种,从而同时增加了Rh基催化剂的CO解离和插入能力,提高了其活性和C2含氧化合物选择性.另一方面,Mn和Li的添加显著地降低了Rh基催化剂表面H的数量和稳定性.催化剂加氢能力显著降低极大地抑制了CH4的生成,从而有利于C2含氧化合物选择性的进一步提高.     

金属-载体相互作用对CH4/CO2重整反应中Rh基催化剂抗积炭性能的影响

考察了Rh/Al2O3,Rh/SiO2和Rh/CeO2催化剂上金属-载体间相互作用对CH4/CO2重整反应抗积炭性能的影响,并与反应前后催化剂的程序升温还原和程序升温氧化(TPO)测试结果相关联.实验发现,Rh与Al2O3和SiO2载体间的相互作用越强,催化剂还原后Rh的分散度越高,晶粒越小,高分散的Rh表面生成的碳物种CHx越多,其作为活泼的反应中间体越易与CO2反应生成CO和H2.而游离态的Rh还原后晶粒较大,生成的碳物种与CO2反应能力较低,从而导致催化剂失活.TPO和CO2脉冲实验结果表明,反应过程中Rh/CeO2催化剂上反应生成的CHx物种比Rh/Al2O3和Rh/SiO2上的CHx物种更活泼.同时由于Rh-CeO2间独特的相互作用,部分CeO2还原后生成CeO2-x和氧空位,促进CO2分子的活化解离,导致生成的表面氧容易与CHx反应,从而抑制催化剂积炭.     

Rh-Mn-Li/SiO2催化剂上CO加氢制C2含氧化合物:载体硅烷化程度的影响

以三甲基氯硅烷为硅烷化试剂,对硅胶进行不同程度硅烷化预处理,采用浸渍法制备了其负载的Rh-Mn-Li催化剂,用于CO加氢制C₂含氧化合物的反应,并运用红外光谱、N₂吸附-脱附法、C含量测定、透射电镜、H₂程序升温还原和程序升温表面反应等手段对载体和催化剂进行了表征。结果表明,制得的不同硅烷化程度硅胶织构性质变化不大,它们负载的催化剂上Rh平均粒径均在3nm左右,硅烷化对催化剂吸附CO的形态和Rh的还原性能的影响均很小,但随着载体硅烷化程度的提高,催化剂上Rh解离CO的能力增加,因而其活性逐渐增加,且不影响C₂含氧化合物的选择性。     

CO加氢Rh-Mn-Li/SiO2催化剂配比的优化及其CO脱附行为

通过优化Rh-Mn-Li/SiO2催化剂配比,大大地提高了其催化CO加氢合成C2含氧化合物的性能,并利用吸附CO的程序升温脱附(CO-TPD)和程序升温表面反应(TPSR)等方法考察了助剂Mn和Li对Rh基催化剂表面CO脱附行为的影响.结果表明,在543~573K内,Rh担载量为1.5%时催化剂的Rh效率(ERh)最高.少量Mn的添加显著地提高了Rh基催化剂的ERh,C2含氧化合物的时空收率(STYC2-oxy)和选择性(SC2-oxy).并且随着Mn含量增加,ERh和STYC2-oxy在Mn=0.53%时最高,但SC2-oxy一直缓慢增加.而随着Li含量增加,SC2-oxy显著增加,但是ERh和STYC2-oxy明显下降.CO-TPD和TPSR结果表明,助剂Mn和/或Li的添加改变了催化剂表面解离CO活性中心的数量及其解离CO的能力,从而影响催化剂的活性.另一方面,Mn和Li的添加提高了催化剂表面弱吸附CO的相对数量,从而使SC2-oxy提高.     

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.     

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.     

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.     

Thermal decomposition of Me3SnO2PCl2, Me2Sn(O2PCl2)2 and Ph3SnO2PCl2

TG and DTA studies on Me₃SnO₂PCl₂, Me₂Sn(O₂PCl₂)₂ and Ph₃SnO₂PCl₂ were carried out under dynamic argon atmosphere. The results show that the decomposition proceeds in different stages leading to the formation of Sn₃(PO₄)₂ as a stable product. This compound was characterized by IR spectroscopy. Decomposition schemes involving reductive elimination reactions were proposed.     

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.     

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.     

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.