掺杂SrTiO3体系上甲烷氧化偶联反应的研究—活性氧物种的作用

本文采用循环氧化还原法,脉冲反应及TPD等实验手段对钙钛矿型氧化物掺杂SrTiO_3体系上甲烷氧化偶联反应中的活性氧物种的作用进行了研究.结果表明,催化剂由于掺杂产生的未被充分还原的氧物种(O~(α-)(0<α<2)是活化甲烷并促使其发生偶联反应的主要的活性中心,而表面晶格氧(O_L~(2-))则主要使甲烷深度氧化;消耗掉的未被充分还原的氧或晶格氧可以在高温下氧气氛中氧化复原.对于掺杂的SrTiO_3样品,体相中的氧在惰性气氛或还原气氛中可以向表面扩散.吸附氧可能不直接与甲烷作用而主要通过催化剂表面活性氧物种(O~(α-)或O_L~(2-))而起作用.     

The Active Oxygen Species for Oxidative Coupling of Methane over CeO_2/BaF_2 Catalyst by in Situ Confocal Microprobe Raman Spectroscopy

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甲烷氧化偶联锂/氧化镁催化剂和纳米催化剂

The Li/MgO catalyst and nanocatalyst were prepared by the incipient wetness impregnation and sol-gel method, respectively. The catalytic performance of the Li/MgO catalyst and nanocatalyst on oxidative coupling of methane was compared. The catalysts prepared in two ways were characterized by X-ray powder diffraction, Brunauer-Emmett-Teller surface and transmission electron microscope. The catalyst was tested at temperature of 973-1073 K with constant total pressure of 101 kPa. Experimental results showed that Li/MgO nanocatalyst in the oxidative coupling of methane would result in higher conversion of methane, higher selectivity, and higher yield of main products (ethane and ethylene) compared to ordinary catalyst. The results show the improved influence of nanoscale Li/MgO catalyst performance on oxidative coupling of methane.     

Oxidative Methylation of Toluene with Methane over K-exchanged Y Type Zeolite Catalyst Promoted with Alkali Metal Bromide and Alkali Metal Oxide

IntroductionManyresearchgroupsareconductingextensiveresearchtoreplacecrudeoil-basedchemicalswithnaturalgasandcoal-basedchemicals.Itisknownthatstyreneisoneofthemostimportantindustrialmonomers.Currently,styreneisproducedbycatalyticalkylationofbenzenewithethyleneoverA1Cl,-HClcata-lyst,followedbyoxidativedehydrogenationoftheresultantethylbenzeneoverpotassium-promotedironoxidecatalystsL'l.However,thisprocessinvolvestheutilizationofbenzeneandethylene,obtainedfromcrudeoilandpetroleumgas,whichareexp…     

WO3-TiO2/SiO2的制备、表征及光催化甲烷和水的反应性能

以表面改性法制备出TiO2／SiO2，进而以浸渍法制备出负载型复合半导体材料WO3-TiO2／SiO3，利用XRD、BET、TPR、UVDRS、IR和TPD等技术对材料的表面性质与构造、光响应性能和化学吸附性能进行了表征，并研究了该材料光催化甲烷和水合成甲醇和氢的反应性能．结果表明：载体有效分散表面物种并使其能隙增大；WO3与TiO2复合所形成的组合活性基元可调变吸光带边并促进对甲烷和水的化学吸附；在100℃以上，光激发WO3-TiO2／SiO2表面产生的光生空穴，促使分子吸附态的甲烷解离并向甲醇转化，形成一定的“光-表面-热”协同作用促使反应顺利进行，对甲醇的选择性达到83％以上．     

Dual Catalysis of Gold Nanoclusters: Photocatalytic Cross-Dehydrogenative Coupling by Cooperation of Superatomic Core and Molecularly Modified Staples**

Thiolate-protected gold nanoclusters (AuNCs) have attracted significant attention as nano-catalysts, revealing a superatomic core and gold-thiolate staples as distinct structural units. Here, we demonstrate the unprecedented dual catalytic activity of thiolate-protected [Au₂₅(SR)₁₈]⁻ nanoclusters, involving both photosensitized ¹O₂ generation by the Au₁₃ superatomic core and catalytic carbon-carbon bond formation facilitated by Au₂(SR)₃ staples. This synergistic combination of two different catalytic units enables efficient cross-dehydrogenative coupling of terminal alkynes and tertiary aliphatic amines to afford propargylamines in high yields of up to 93 %. Mixed-ligand AuNCs bearing both thiolate and alkynyl ligands revealed the intermediacy of the alkynyl-exchanged AuNCs toward both photosensitization and C−C bond-forming catalytic cycles. Density functional theory calculations also supported the intermediacy of the alkynyl-exchanged AuNCs. Thus, the use of ligand-protected metal nanoclusters has enabled the development of an exceptional multifunctional catalyst, wherein distinct nanocluster components facilitate cooperative photo- and chemo-catalysis.     

氟化锶／氧化钕催化剂的甲烷氧化偶联性能及其吸附氧物种的原位FTIR光谱研究

氟化锶／氧化钕催化剂的甲烷氧化偶联性能及其吸附氧物种的原位ＦＴＩＲ光谱研究龙瑞强，万惠霖，赖华龙，蔡启瑞（厦门大学化学系固体表面物理化学国家重点实验室，厦门，３６１００５）关键词甲烷氧化偶联，氟化锶／氧化钕，吸附氧物种近年来，甲烷氧化偶联（ＯＣＭ）的...     

Metallation of Ligands with Biological Activity: Synthesis and X‐ray Characterization of the New Sulfathiazolato Complexes of Gold(I) and Silver(I): [(sulfathiazolato)AuPPh3] and [Ag(sulfathiazolato)]2 (sulfathiazole = N1‐2‐thiazolyl‐sulfanilamide)

Sulfathiazole reacts with [Ph₃PAu(CH₃COO)] in benzene and with Ag(CH₃COO) in methanol giving [(sulfathiazolato)AuPPh₃] ( 1 ) and {[Ag(sulfathiazolato)]₂}_n ( 2 ). While the lattice of 1 contains single molecules with linear N–Au–P bonds, compound 2 performs a polymeric, one‐dimensional assembling of [Ag(sulfathiazolato)]₂ dimers linked through intermolecular Ag···O=S=O interactions along the crystallographic axis b. The silver atoms achieve a tetrahedral configuration through Ag–Ag contacts which measure 2.8427(4) Å, considerably shorter than the normal bonding distance of metallic silver.