用核磁共振技术研究氢键的键合方式

为了了解怎样利用核磁共振技术研究氢键的键合方式,本文以联酰胺衍生物为例,分别运用变温核磁共振氢谱和变浓度核磁共振氢谱分析了羰基(CO)与氨基(H—N)之间形成氢键的形式。结果表明,本文举例中联酰胺基团中的CO与H—N以分子间氢键形式存在。     

草酰胺导向下钯催化的C(sp~2)—H和C(sp~3)—H键的直接酰氧基化反应

成功地发展了一种草酰胺导向的钯催化的过氧化苯甲酸叔丁酯为氧化剂的C(sp~2)—H和C(sp~3)—H键的酰氧基化反应.草酰胺基保护的苄胺用过氧化苯甲酸叔丁酯或羧酸为酰氧基化剂可以选择性地进行C(sp~2)—H键的酰氧基化,而草酰氨基保护的2-烷基苯胺则可以进行苄基位C(sp~3)—H键的酰氧基化反应.该方法为芳香酸酯类化合物的合成提供了一种方便、有效的方法.     

用红外光谱技术研究氢键的键合方式

氢键的形成能够使参与形成氢键的原化学键力常数降低,吸收频率移向低波数方向,同时吸收强度增加。为了介绍怎样利用红外光谱技术研究氢键的键合方式,本文以联酰胺衍生物为例,主要运用变温红外光谱技术分析NH伸缩振动波数、强度以及形成氢键的键长随温度的变化来研究羰基(C O)与氨基(H—N)之间的氢键形式。结果表明,本文举例中联酰胺基团中的C O与H—N以分子间氢键形式存在。     

醋酸铜促进的酰胺-噁唑啉化合物与芳基硫醇的C—H键双硫代化反应研究

以酰胺-噁唑啉为辅助基团,在廉价的醋酸铜促进下,实现了酰胺衍生物C(sp2)—H键与芳基硫醇S—H键的脱氢偶联反应;以中等到优秀的产率(最高可达90%)简单高效地合成了一系列双硫化的酰胺衍生物.值得一提的是,底物范围并不局限于各种取代苯基酰胺化合物,吡啶基酰胺化合物也可以兼容.该反应的特点是:金属廉价、底物范围广、反应条件温和、无需外加配体、空气作为氧化剂、区域选择性好(仅酰胺基团邻位的C—H键发生反应,而噁唑啉基团邻位的C—H键不发生反应);此外,克级规模的反应表明了其在合成中的实用性.     

中性团簇(CeO_2)_m(m=1～3)活化甲烷C—H的密度泛函理论计算

采用密度泛函理论(DFT)计算了CH4在电中性(Ce O2)m(m=1~3)团簇上的活化情况,并对其机理进行了探讨.计算结果表明,甲烷C—H键在团簇上的活化为亲核加成模式,电子由团簇流向甲烷C—H反键轨道,使甲烷C—H键削弱而得以活化,反应的过渡态为四中心结构.团簇的桥氧位活化甲烷C—H键的活性大于端氧位,而三重桥氧位的活性高于二重桥氧位.团簇中作用位点Ce和O原子的电荷布居与其活化甲烷C—H的能力密切相关.溶剂的存在不仅降低了甲烷C—H活化自由能垒,而且使与甲烷作用的团簇各位点的活性差异缩小.     

新型苯环5-(取代)苯甲酰胺基苯磺酰脲类化合物的比较定量构效关系研究

采用比较分子力场分析(CoMFA)方法, 对26个新型苯环5-(取代)苯甲酰胺基苯磺酰脲类化合物的除草活性进行了三维定量构效关系(3D-QSAR)研究, 建立了三维定量构效关系CoMFA模型(R²=0.948, F=91.364, SE=0.141). 结果表明, 此类磺酰脲类化合物的除草活性与苯环5位取代基的立体结构和电场性质密切相关. 根据CoMFA模型的立体场和静电场三维等值线图不仅直观地解释了结构与活性的关系, 而且为进一步设计高活性的目标化合物提供理论依据.     

N^2（p—甲基苯磺酰）—L—谷氨酰胺的晶体结构测定

谷氨酰胺衍生物抗瘤酮A_(10)(3-苯乙酰胺基-2,6-哌啶二酮)是从人尿、血液中分离出来的天然广谱性抗肿瘤活性化合物,无明显毒副作用,目前正进行Ⅱ期临床研究.其抗肿瘤的有效成分被认为是它的2个水解产物苯乙酰谷氨酰胶和苯乙酰异谷氨酰胺。De和Pal曾对抗瘤酮A_(10)的类似物如3-对甲苯磺酰胺基-2,6-哌啶二酮等做过抗艾氏腹水癌活性评价,探讨了构效关系.但未见这些化合物的空间结构和电子结构方面的报道.我们合成了抗艾氏腹水癌活性较高的化合物3-对甲苯磷酰胺基-2,6-哌啶二酮的水解产物——对甲苯磺酰谷氨酰胺,并测定了其晶体结构。为进一步研究其分子结构与抗肿瘤活性的关系提供结构数据。     

酰胺接枝ACF的制备及其在处理水体中重金属Cu2+的应用

利用聚丙烯腈基活性碳纤维(PAN-ACF)表面存在的羧基与氯化亚砜SOCl2发生酰氯化反应后与乙二胺110℃加热回流在其表面接枝胺基、酰胺基团对其进行改性,用傅立叶转换红外光谱仪(FTIR)、X射线光电子能谱仪(XPS)对改性前后活性碳纤维的表面结构和元素结合态及含量变化进行了表征,并将改性后的活性碳纤维(NH-ACF)应用于水体中Cu2+离子的去除处理,用电感耦合等离子体原子发射光谱仪(ICP-AES)检测被处理溶液中的Cu2+离子浓度变化,进而得出Cu2+离子在NH-ACF上的最大吸附量qmax.结果表明,NH-ACF比未改性处理的PAN-ACF对Cu2+吸附去除能力具有显著的优势,前者约为后者的1.5倍.     

Grafting Amide onto Activated Carbon Fiber's Surface and Its Application in the Disposal of Heavy Metal Ion Cu2+

利用聚丙烯腈基活性碳纤维(PAN-ACF)表面存在的羧基与氯化亚砜SOCl2发生酰氯化反应后与乙二胺110℃加热回流在其表面接枝胺基、酰胺基团对其进行改性,用傅立叶转换红外光谱仪(FTIR)、X射线光电子能谱仪(XPS)对改性前后活性碳纤维的表面结构和元素结合态及含量变化进行了表征,并将改性后的活性碳纤维(NH-ACF)应用于水体中Cu2+离子的去除处理,用电感耦合等离子体原子发射光谱仪(ICP-AES)检测被处理溶液中的Cu2+离子浓度变化,进而得出Cu2+离子在NH-ACF上的最大吸附量qmax.结果表明,NH-ACF比未改性处理的PAN-ACF对Cu2+吸附去除能力具有显著的优势,前者约为后者的1.5倍.     

C(2)-酰胺基-4-芳基-1,5-苯并硫氮杂的合成及抑菌活性的研究

设计合成了三类C(2)酰胺基取代的1,5-苯并硫氮杂衍生物:2-酰胺基(N-芳基)-4-芳基-1,5-苯并硫氮杂、2-酰胺基(N-烷基)-4-芳基-1,5-苯并硫氮杂和2-酰胺基(N,N-二烷基)-4-芳基-1,5-苯并硫氮杂,其结构用元素分析,IR,MS及1H NMR确证.测定了目标化合物的抑真菌活性,结果表明部分化合物对新生隐球菌具有中等强度的抑真菌活性.还研究了2-酰胺基-4-芳基-1,5-苯并硫氮杂的合成反应条件.     

Oligo(p-phenylene-ethynylene)s with backbone conformation controlled by competitive intramolecular hydrogen bonds

A series of conjugated oligo(p-phenylene-ethynylene) (OPE) molecules with backbone conformations (that is, the relative orientations of the contained phenylene units) controlled by competitive intramolecular hydrogen bonds to be either co-planar or random were synthesised and studied. In these oligomers, carboxylate and amido substituents were attached to alternate phenylene units in the OPE backbone. These functional groups were able to form intramolecular hydrogen bonds between neighbouring phenylene units. Thereby, all phenylene units in the backbone were confined in a co-planar conformation. This planarised structure featured a more extended effective conjugation length than that of regular OPEs with phenylene units adopting random orientation due to a low rotational-energy barrier. However, if a tri(ethylene glycol) (Tg) side chain was appended to the amido group, it enabled another type of intramolecular hydrogen bond, formed by the Tg chain folding back and the contained ether oxygen atom competing with the ester carbonyl group as the hydrogen-bond acceptor. The outcome of this competition was proven to depend on the length of the alkylene linker joining the ether oxygen atom to the amido group. Specifically, if the Tg chain folded back to form a five-membered cyclic structure, this hydrogen-bonding motif was sufficiently robust to overrule the hydrogen bonds between adjacent phenylene units. Consequently, the oligomers assumed non-planar conformations. However, if the side chain formed a six-membered ring by hydrogen bonding with the amido NH group, such a motif was much less stable and yielded in the competition with the ester carbonyl group from the adjacent phenylene unit. Thus, the hydrogen bonds between the phenylene units remained, and the co-planar conformation was manifested. In our system, the hydrogen bonds formed by the back-folded Tg chain and amido NH group relied on a single oxygen atom as the hydrogen-bond acceptor. The additional oxygen atoms in the Tg chain made a negligible contribution. A bifurcated hydrogen-bond motif was unimportant. From our results, in combination with the results from an independent study by Meijer et al., it is evident that intramolecular hydrogen bonds involving back-folded oligo(ethylene glycol) moieties may differ in their structural details. Absorption spectroscopy served as a convenient yet sensitive technique for analysing hydrogen-bonding motifs in our study.     

Conformation of secondary amides. A predictive algorithm that correlates DFT-calculated structures and experimental proton chemical shifts

The magnetic deshielding caused by the amido group on CON-CHalpha protons of secondary amides can easily be correlated with DFT-based structures at the B3LYP/6-31G level of theory via a novel algorithm that refines previous models, such as the classical McConnell equation. The shift is given by delta = a + 2.16 cos2(alpha - 35)/d, where alpha denotes the virtual dihedral angle resulting from linking the carbonyl and the alpha-carbons and d is the distance (A) between the shifted proton and the carbonyl oxygen. Notably, in this equation a is a parameter that can be optimized for different solvents, namely, CDCl3, DMSO-d6, and D2O. For the development of these correlations, the preferential conformation of amides is taken from the optimized structures in the gas phase obtained at the DFT level. The deshielding on anti and gauche protons in both rotamers of (Z)-acetamides and E/Z isomers of formamides has been evaluated. This methodology has proved to be highly reliable, allowing us to discard ab initio or DFT conformational arrangements when shifts calculated by the above-mentioned equation differ from the experimental values. Thus, the anti disposition between the CHalpha proton and the N-H bond appears to be the more stable conformation of simple amides. For amides bearing only one proton at Calpha, a local syn minimum can equally be characterized. The rotational barriers around the CON-alkyl bond along with the pyramidalization of the amido group have also been reassessed. As the conformation is taken away from anti or local syn minima, the nonplanarity of the amido group appears to increase.     

Synthesis and characterisation of new bimetallic alkali metal-magnesium mixed diisopropylamide-acetylides: structural variations in bimetallic lithium- and sodium-heteroleptic magnesiates

The reactivity of the Br?nsted basic mixed-metal tris-amide compounds of empirical formula [MMg(N(i)Pr2)3] [where M = Li (1), Na (2)] towards phenylacetylene (HC[triple bond, length as m-dash]CPh) has been investigated and has led to the synthesis of a series of mixed-metal acetylido-amido-magnesiates. Thus, 1 and 2 molar equivalents of the alkyne with [MMg(N(i)Pr2)3] produce heteroanionic bis(amido)-mono(acetylido) [LiMg(N(i)Pr2)2(C[triple bond, length as m-dash]CPh)]2 (3) and mono(amido)-bis(acetylido) [(TMEDA) x Na(C[triple bond, length as m-dash]CPh)2Mg(N(i)Pr2)](2) (4) (TMEDA = N,N,N',N'-tetramethylethylenediamine) respectively. X-Ray crystallographic studies reveal that the new compounds adopt a different structural motif. Complex can be defined as an inverse crown structure, having a cationic eight-atom [(NaNMgN)2]2+ ring which hosts in its core two acetylido ligands. On the other hand, adopts a tetranuclear NaMgMgNa near-linear chain arrangement, held together by acetylido and amido bridges. The metal coordination geometries in both structures are distorted tetrahedral, and the sodium cations at the end of the mixed-metal chain carry terminal chelating TMEDA ligands. 1H and 13C NMR spectral data recorded in C6D6 solutions are also reported for and , and are consistent with the solid-state structures being retained in solution.     

Amido‐3‐hydroxypyridin‐4‐ones as Iron(III) Ligands

The synthesis and physicochemical properties of a range of 2‐ and 6‐amido‐3‐hydroxypyridin‐4‐ones are described. All the amido‐substituted 3‐hydroxypyridin‐4‐ones have lower pK_a values than 1,2‐dimethyl‐3‐hydroxypyridin‐4‐one (deferiprone). This is due to the inductive effect of the amido group. Furthermore, the pK_a values of the 3‐hydroxy group in 1‐nonsubstituted pyridinones are dramatically lower than those of the corresponding 1‐alkyl analogues, indicating that a strong hydrogen bond exists between the 2‐amido function and the 3‐oxygen anion, which stabilises the anion. As a result of the decreased competition with protons, the pFe³⁺ values of this group of molecules are higher than that of deferiprone. The distribution coefficients of these molecules are also increased despite the lack of a hydrophobic 1‐alkyl substituent and this is ascribed to the intramolecular hydrogen bond. X‐ray diffraction studies confirm the existence of the intramolecular hydrogen bond.     

10-十一烯酸衍生物混合体系有序溶液与聚集体研究

对三甲基－[2-(10-十一烯酰氧乙基）]碘化铵CH2＝CH（CH2）8COOCH2CH2N（CH3）3I和N，N－[2-(10-十一烯酰甲基牛磺酸钠）]CH2＝CH（CH2）8CON（CH3）CH2CH2SO3Na的表面及聚集行为进行了研究。混合体系溶解度良好，在40cmc时仍为稳定胶团溶液。结合正规溶液理论计算了混合体系表面吸附层、胶团的组成及分子间作用参数。基于两亲分子几何结构及分子间相互作用原理对上述现象进行了合理解释，发现了少量长链脂肪醇促使正负离子表面活性剂混合胶团转化为囊泡的新现象。     

Molecular Design And Properties Prediction Of Cyclotetramethylene Tetranitramine (Hmx) Derivatives With Amido Groups

DFT/BLYP/DNP method was employed to calculate the total energy of cyclotetramethylene tetranitramine (HMX) derivatives modified with amido groups and the bond dissociation energy of the weakest N-NO₂ bond. The bond dissociation energy decreases with the number of amido groups. Isodesmic reactions were used to calculate standard molar enthalpies of formation of the derivatives; these values increase with the number of amido groups but not according to additivity rules. Entropy and heat capacity were also investigated. NBO analysis was applied to study the bond orders and the second perturbation energy of the N-NO₂ bonds; these parameters decrease regularly with the number of amido groups. Taking a single amido derivative as an example to analyze the vibration frequencies, it is shown that all the strongest vibrations are related with the N-NO₂ bonds.     

X-ray Crystal Structure and Molecular Mechanics Calculations of (2,6-iso-dipropyl-phenylamide) Dimethyl ( tetra-methylcyclopenta-dienyl ) Silane Titanium Dichloride

Crystal and molecular structure of (2,6-dipropylphenylamide) dimethyl (tetra-methyl cyclopentadienyl) silane titanium dichloride (I) was fully characterized by X-ray diffraction. The crystal is obtained from a mixture of ether/hexane as orthorhombic, with a = 12.658 (3) (A), b = 16.62 (3)(A), c = 11.760 (2)(A), V = 2474.2 (9)(A) 3, Z = 4, space group Pnma, R = 0.0399. Componud I compose of the π-bounded ring with its dimethylsilyl-dipropyl phenyl amido group and the two terminal chloride atoms coordinated to central metal to form a so-called constrained geometry catalyst (CGC) structure. The result of molecular mechanics (MM) calculations on compound I shows that bond lengths and bond angles from the MM calculation are comparable to the data obtained from the X-ray diffraction study. The relation of the structure of CGCs and their catalytic activity by MM calculations is also discussed.     

X-ray Crystal Structure and Molecular Mechanics Calculations of (2,6-iso-dipropyl-phcnylamidc) Dimethyl (tetra-methylecyclopenta- dienyl)Silane Titanium Dichloride

ExperimentalSynthesisofitToI.sg(4mmol.)TiCI,.THFin25mLTHFwasaddedI.sg(4mmol.)dilithium(2,6-propylphenylamide)dimethyl(tetra-methylcyclopentadienyl)silaneandthemixturewasallowedtostirforIhour,then0.639AgCI(4mmol.)wasadded.After4hoursstirring,thesolventwasmovedandtheresiduewasextractedwithdiethylether.Theetherextractwasfilteredandevaporatedtodrynesstogive0.409yellowcrystallinesolid,yield41%.'H-NMR(C,D,)f0.48(6H),l.I2(6H),l.49(6H),l.98(6H).2.18(6H),and3.04(2H).Asuitablesinglecrystalwa…     

Intramolecular Nitrene Insertion into Saturated C−H-Bond-Mediated C−N Bond Cleavage of a Coordinated NHC Ligand

Ruthenium(II) complexes bearing a tridentate bis(N-heterocyclic carbene) ligand reacted with iminoiodanes (PhI=NR) resulting in the formation of isolable ruthenium(III)–amido intermediates, which underwent cleavage of a C−N bond of the tridentate ligand and formation of an N-substituted imine group. The Ru^III–amido intermediates have been characterized by ¹H NMR, UV/Vis, ESI-MS, and X-ray crystallography. DFT calculations were performed to provide insight into the reaction mechanism.     

Tris(bis(trimethylsilyl)amido)samarium: X-ray structure and DFT study

The compound Sm[N(SiMe(3))(2)](3) has been investigated experimentally by X-ray crystallography and computationally by DFT methods. The structure is analogous to that of other tris[bis(trimethylsilyl)amido]lanthanides, featuring positional disorder of the metal atom above and below the plane defined by the three N donor atoms, resulting in a trigonal pyramidal configuration. One of the methyl groups of each amido ligand is placed above the apex of the pyramid at close distance to the metal center suggesting the presence of agostic interactions. The DFT calculations have been carried out on the real molecule and on a Si[N(SiH(3))(SiH(2)Me)](3) model where the unique Me group was placed above the apex of the pyramid to probe the agostic interaction. In both cases, the optimized geometry reproduces very well the experimental structure and indicates the presence of beta-Si-C agostic interactions. A comparison of the optimized geometries obtained in the presence/absence of the Sm d and the Si d orbitals serves to illustrate the relevance of these orbitals for (i). the establishment of the pyramidal configuration at Sm, (ii). the Sm-N bond length, and (iii). the Sm-(beta-Si-C) bond length. The bonding analysis, which was carried out by both Mulliken and NBO methods, not only confirms the importance of the metal d orbitals for the Sm-N and Sm-(beta-Si-C) chemical bonding but also illustrates the relevance of electrostatic terms in the agostic interaction. Sm-N and N-Si pi bonding is present according to the bonding analysis but is not important for enforcing the planar configuration at N, nor the pyramidal configuration at Sm.