硫化氢对冻胶型堵剂的影响

研究了H2S对常规冻胶型堵剂成冻时间和冻胶强度的影响,这些冻胶型堵剂包括交联聚丙烯酰胺形成的铬冻胶和酚醛树脂冻胶.探讨了H2S对冻胶型堵剂影响的作用机理.结果表明:H2S对无机铬交联体系的影响较大,而对有机铬交联体系和酚醛树脂交联体系的影响相对较小;对于无机铬交联体系,H2S能迅速将Cr6+还原为Cr3+,提高交联HPAM的速度,而当H2S含量偏高时,被还原出的Cr3+会与过量的H2S生成Cr2S3沉淀,不能形成整体冻胶;对有机铬和酚醛树脂交联体系的影响主要体现在pH值的变化上.当选择冻胶型堵剂应用于含H2S的油气藏时,最好选用酚醛树脂冻胶.     

含联硫磷配体的六核钴羰合簇的合成与表征

Ｃｏ２（ＣＯ）８与前配体ＰＲＳ２）２（Ｒ＝Ｃ６Ｈ４Ｃｐｈ,Ｃ６Ｈ４ＯＥｔ）反应,合成得到含前配体劈开的Ｓ与ＳＰＲ分子片的新颖六核钴羰合簇Ｃｏ６（μ３－Ｓ）２（ＣＯ）１４（μ４－η＾２－ＳＰＣ６Ｈ４Ｏｐｈ）（Ｉ）和Ｃｏ６（μ３－Ｓ）２（ＣＯ）１４（μ４－η＾２－ＳＰＣ６Ｈ４ＯＥｔ）（Ⅱ）,对它们进行了元素分析,ＩＲ,ＨＮＭＲ〈＾３１ＰＮＭＲ和ＭＳ表征,该类簇合物有一个与四个金属原子相联的罕见的联硫磷     

聚苯硫醚相对分子质量分布的计算机模拟测定

研究应用熔体动态粘弹性质测定聚苯硫醚相对分子质量分布方法。采用流变仪测定聚苯硫醚熔体动态储能模量、动态耗能模量、动态剪切粘度等流变性数据,用零动态剪切粘度数值确定重均相对分子质量。应用双滑动链环流变性分子动力学模型,根据平台模量,特征松弛时间等独立参数,模拟计算熔体动态剪切粘度理论值,和实验测试值拟合,得到相对分子质量分布系数。该法为测定200℃以下不溶于任何有机溶剂的聚苯硫醚相对分子质量分布,提供了一种实际有效的方法。     

羧酸甲乙酯中羰基17O-NMR化学位移研究

提出了计算羧酸甲乙酯中羰基¹⁷O-NMR化学位移的公式：δ_cal（¹⁷O）=360.0+Δα+Δβ+Δγ,通过线性回归法确定了22种取代基参数.经回归检验表明该公式计算结果置信度为99.5%,与实验值的偏差Δδ在5.0以内的羰基¹⁷O-NMR化学位移计算值~100%.     

H2S在Fe(100)面吸附的第一性原理研究

基于密度泛函理论第一性原理, 在广义梯度近似下, 研究了表面覆盖度为0.25 ML (monolayer)时硫化氢分子在Fe(100)面吸附的结构和电子性质, 并与单个硫原子吸附结果进行了对比. 结果表明: 硫化氢分子吸附在B2位吸附能最小为-1.23 eV, 最稳定, B1位吸附能最大为-0.01 eV, 最不稳定; 并对硫化氢分子在B1位和B2位吸附后的电子态密度进行了分析, 也表明了吸附在B2位稳定, 且吸附在B2位后硫化氢分子几何结构变化不大; 将硫化氢中硫原子吸附与单个硫原子吸附的电子性质进行了比较, 发现前者吸附作用非常微弱; 同时对吸附后的Fe(100)面进行了对比, 单个硫原子吸附的Fe(100)面电子态密度出现了一系列峰值且离散分布, 生成了硫化亚铁, 表明在硫化氢环境下, 主要是硫化氢析出的硫原子发生了吸附. 关键词： 第一性原理 Fe(100)表面 吸附能 硫化氢     

Mechanochemical synthesis of PbS/Ni–Cr layered double hydroxide nanocomposite

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Convenient and Efficient Synthesis of 1,1‐Bis‐(4‐alkylthiophenyl)‐1‐alkenes via Tandem Friedel–Crafts Acylation and Alkylation of Sulfides and Acyl Chlorides

1,1‐Bis(4‐alkylthiophenyl)‐1‐alkenes were conveniently and efficiently prepared from alkyl phenyl sulfides and acyl chlorides via a tandem Friedel–Crafts acylation and alkylation in the presence of anhydrous aluminum chloride. The scope, limitation, and mechanism of the tandem reaction were also discussed.     

H2S splitting on Cu(110): Insight from combined periodic density functional theory calculations and microkinetic simulation

Practical copper (Cu)‐based catalysts for the water–gas shift (WGS) reaction was long believed to expose a large proportion of Cu(110) planes. In this work, as an important first step toward addressing sulfur poisoning of these catalysts, the detailed mechanism for the splitting of hydrogen sulfide (H₂S) on the open Cu(110) facet has been investigated in the framework of periodic, self‐consistent density functional theory (DFT‐GGA). The microkinetic model based on the first‐principles calculations has also been developed to quantitatively evaluate the two considered decomposition routes for yielding surface atomic sulfur (S*): (1) H₂S → H₂S* → SH* → S* and (2) 2H₂S → 2H₂S* → 2SH* → S* + H₂S* → S* + H₂S. The first pathway proceeding through unimolecular SH* dissociation was identified to be feasible, whereas the second pathway involving bimolecular SH* disproportionation made no contribution to S* formation. The molecular adsorption of H₂S is the slowest elementary step of its full decomposition, being related with the large entropy term of the gas‐phase reactant under realistic reaction conditions. A comparison of thermodynamic and kinetic reactivity between the substrate and the close‐packed Cu(111) surface further shows that a loosely packed facet can promote the S* formation from H₂S on Cu, thus revealing that the reaction process is structure sensitive. The present DFT and microkinetic modeling results provide a reasonably complete picture for the chemistry of H₂S on the Cu(110) surface, which is a necessary basis for the design of new sulfur‐tolerant WGS catalysts. © 2013 Wiley Periodicals, Inc.     

Reaction of 4-(2′-Hydroxyaryl)-1,3-dithiolium Salts with Sodium Sulfide. A Selective Synthesis of 2′-Hydroxyacetophenones

Abstract

The treatment of 4-(2′-hydroxyaryl)-2-(N,N-dialkylamino)-1,3-dithiolium perchlorates (1a–g) with sodium sulfide nonahydrate in ethanol at room temperature affords the corresponding 1,3-dithiole-2-thiones (2a–g). When these reactions are conducted in boiling ethanol, 2′-hydroxyacetophenones (3a–g) have been obtained in good to excellent yield. A tentative mechanism for the formation of 3a–g shows that this reaction is regioselective, this being established by the presence of hydroxyl group in 2′-position. That has been confirmed in a control experiment, 4-phenyl-2-(piperidin-1-yl)-1,3-dithiolium perchlorate affording a mixture of condensation products of acetophenone and phenylacetaldehyde, under similar reaction conditions.     

Surface-Modified Sb2S3 Nanoparticles and Their Tribological Behaviors in Liquid Paraffin

Sb₂S₃ nanoparticles surface-modified with S-tetradecyl N, N-dihydroxyethyl dithiocarbamate (C₁₄DTC-Sb₂S₃) have been synthesized via extraction of Sb₂S₃ colloidal particles from ethylene glycol into toluene in the presence of C₁₄DTC. The obtained products were characterized by high-resolution transmission electron microscope (HRTEM) and Fourier transformation infrared (FTIR), and their tribological behaviors as an additive in liquid paraffin were investigated using a four-ball tribometer. The results show that C₁₄DTC-Sb₂S₃ nanoparticles can significantly improve the friction reduction, anti-wear, and load-carrying properties of base oils. The preliminary lubrication mechanism was discussed based on the SEM and XPS investigation of the rubbed surfaces.