L-天冬氨酸锌螺旋链状超分子聚合物的微波合成、晶体结构及其毒性研究

用L-天冬氨酸、氧化锌在微波辐射下方便、快速、高产率的合成了L-天冬氨酸锌, 并通过X射线衍射确定了其单晶结构. 晶体结构表明, 该配合物以包含了一分子结晶水的二环状[Zn(L-Asp)(H₂O)₂]为结构单元, 通过配位键形成了一种螺旋链状的聚合物. 该聚合物链又通过分子间氢键组装成了一个三维网状的超分子体系. 晶体属于正交晶系, P2(1)2(1)2(1) 空间群, a = 0.7830(3), b = 0.9369(4), c = 11.599(5) nm, α =β =γ = 90.00°, V = 0.8509(6)nm³, Z = 4, Dc = 1.955 g/cm³, F(000) = 512, μ = 2.289. 毒性试验表明标题化合物的毒性比谷氨酸锌、硫酸锌低.     

钆在柠檬酸(L-天冬氨酸)、L-丝氨酸(L-苏氨酸)三元水相体系中的化学形态

钆化学形态;钆在柠檬酸(L-天冬氨酸)、L-丝氨酸(L-苏氨酸)三元水相体系中的化学形态     

氢键在现代化学中的作用

在各种分子间相互作用中,氢键占有很特殊的地位,被称作为超分子化学中的万能相互作用。讨论了氢键在超分子、自组装、分子识别、晶体工程、材料化学和催化过程等现代化学领域中的作用。     

基于弱氢键相互作用形成的层状有机超分子晶体

合成了双吡啶双西佛碱(bped)有机分子,并用该分子进行了超分子网络晶体的组装.X射线单晶结构分析结果表明,该晶体属单斜晶系,P2(1)/c空间群,晶胞参数为a=1.340 14(15)nm,b=0.421 53(11)nm,c=1.115 05(4)nm,β=101.660(4)°,V=0.616 90(18)nm3,Z=2,R=0.064 8.在bped晶体中存在着分子间氢键相互作用,该氢键由N原子和H—C中的H原子相互作用而成.每一个bped分子同另外6个bped分子通过氢键相连,构成了二维层状结构.     

化妆品级聚天冬氨酸钠的制备

以L-天冬氨酸为起始原料通过缩合聚合合成了化妆品级的聚天冬氨酸钠(PASP)。 详细考察了聚合温度、聚合时间及催化剂用量对聚合反应的影响,筛选出最优的聚合条件。 利用核磁共振波谱仪(NMR)及凝胶渗透色谱(GPC)对PASP的结构及相对分子质量进行表征,同时也对其耐酸碱性、耐温性及兼容性进行了评估。 结果表明,所制备的PASP颜色浅、气味小、杂质少、品质高并具有良好的耐酸碱性、耐温性及兼容性,达到了化妆品的使用标准,可作为保湿剂添加到化妆品中。     

基于氢键作用结合的超分子聚合物

非共价键结合的超分子聚合物由于其特殊的结构及性能引起了广泛的关注.本文在介绍超分子化学、氢键及超分子聚合物的基础上,主要综述了以氢键为结合力的多重氢键作用、羧基(D)与吡啶基(A)作用以及氢键与其它非共价键协同作用形成的超分子聚合物体系,并对超分子聚合物的研究现状及前景进行了评述.     

基于氢键作用结合的超分子聚合物

非共价键结合的超分子聚合物由于其特殊的结构及性能引起了广泛的关注。本文在介绍超分子化学、氢键及超分子聚合物的基础上,主要综述了以氢键为结合力的多重氢键作用、羧基（D）与吡啶基（A）作用以及氢键与其它非共价键协同作用形成的超分子聚合物体系,并对超分子聚合物的研究现状及前景进行了评述。     

基于氢键作用结合的超分子聚合物

非共价键结合的超分子聚合物由于其特殊的结构及性能引起了广泛的关注。本文在介绍超分子化学、氢键及超分子聚合物的基础上,主要综述了以氢键为结合力的多重氢键作用、羧基(D)与吡啶基(A)作用以及氢键与其它非共价键协同作用形成的超分子聚合物体系,并对超分子聚合物的研究现状及前景进行了评述。     

银掺杂聚L-天冬氨酸修饰电极的制备及对肾上腺素的测定

利用循环伏安法,研究了银和L-天冬氨酸在玻碳电极表面电化学聚合的条件,制备了银掺杂聚L-天冬氨酸修饰电极。研究了肾上腺素在修饰电极上的电化学行为,建立了循环伏安法测定肾上腺素的新方法。在pH=3.5的磷酸盐缓冲溶液中,扫描速率为50mV/s时,肾上腺素在修饰电极上产生一对明显的氧化还原峰,峰电位分别为Epa=0.447V,Epc=0.387V。用循环伏安法测定时,氧化峰电流与肾上腺素浓度分别在8.00×10-8～1.00×10-5mol/L和1.00×10-5～1.00×10-4mol/L范围内呈良好的线性关系,检出限为8.0×10-9mol/L。     

银掺杂聚L-天冬氨酸修饰电极的制备及对多巴胺的测定

利用循环伏安法将银与L-天冬氨酸聚合修饰在玻碳电极表面,制成银掺杂聚L-天冬氨酸修饰电极,研究了多巴胺在此电极上的电化学行为,建立了循环伏安法测定多巴胺的新方法.在磷酸盐缓冲溶液(PBS, pH 7.0)中,扫描速率为50 mV/s时,多巴胺在修饰电极上产生一对氧化还原峰,Epa=0.191 V,Epc=0.161 V.用循环伏安法进行测定时,峰电流与多巴胺浓度分别在3.0×10-7 ～1.0×10-5 mol/L和1.0×10-5 ～5.0×10-4 mol/L内呈良好的线性关系; 检出限为5.0×10-8 mol/L.用于药物和尿样中多巴胺的测定,结果满意.     

Supramolecular triads bearing porphyrin and fullerene via ‘two-point’ binding involving coordination and hydrogen bonding

Supramolecular triads composed of fullerene (C₆₀) as primary electron acceptor, zinc porphyrin (ZnP) as primary electron donor, and either a ferrocene (Fc), or N,N-dimethylaminophenyl (DMA), or N,N-diphenylaminophenyl (DPA) entity as a second electron donor were constructed via a ‘two-point’ binding motif involving axial coordination and hydrogen bonding. The B3LYP/3-21G(*) optimized structures revealed disposition of the three entities of the triads in a triangular fashion. The redox behavior of the different components was studied using cyclic voltammetry in o-dichlorobenzene containing 0.1 M (n-C₄H₉)₄NClO₄. The oxidation potentials of the second electron donor followed the trend: Fc<DMA<DPA, and the free-energy calculations suggested the possibility of the occurrence of sequential hole transfer in these triads. Efficient electron transfer from the excited singlet state of zinc porphyrin to the fullerene entity was observed in all of the studied triads in o-dichlorobenzene. Longer charge-separated states were observed for zinc porphyrin with a carboxylic acid compared with that having an amide group. The ratios of the experimentally determined forward to reverse electron transfer rates, k_CS/k_CR were evaluated to be 10³ for triads formed by zinc porphyrin with a carboxylic acid, suggesting charge stabilization in these triads.     

On differences between hydrogen bonding and improper blue-shifting hydrogen bonding.

Twenty two hydrogen-bonded and improper blue-shifting hydrogen-bonded complexes were studied by means of the HF, MP2 and B3LYP methods using the 6-31G(d,p) and 6--311 ++G(d,p) basis sets. In contrast to the standard H bonding, the origin of the improper blue-shifting H bonding is still not fully understood. Contrary to a frequently presented idea, the electric field of the proton acceptor cannot solely explain the different behavior of the H-bonded and improper blue-shifting H-bonded complexes. Compression of the hydrogen bond due to different attractive forces-dispersion or electrostatics--makes an important contribution as well. The symmetry-adapted perturbation theory (SAPT) has been utilized to decompose the total interaction energy into physically meaningful contributions. In the red-shifting complexes, the induction energy is mostly larger than the dispersion energy while, in the case of blue-shifting complexes, the situation is opposite. Dispersion as an attractive force increases the blue shift in the blue-shifting complexes as it compresses the H bond and, therefore, it increases the Pauli repulsion. On the other hand, dispersion in the red-shifting complexes increases their red shift.     

Intramolecular hydrogen bonding in calixarenes

The construction of a molecular cavity for recognition and catalysis requires either covalent synthesis or intermolecular self-assembly of complementary units. Intramolecular hydrogen bonding is another tool to control the cavity-forming process. When properly positioned within the same molecular structure, hydrogen bonding sites are responsible for the formation, preorganization, and binding ability of the host. The most typical examples from the supramolecular chemistry of calixarenes, the key cavity-containing building blocks, and derived from them receptor molecules are discussed.     

Structure,hydrogen bonding and vibrational spectra of pyruvic acid

The complete vibrational spectra of liquid pyruvic acid and the infrared spectrum of crystalline pyruvic acid at about 20 K have been recorded and analyzed. A vibrational assignment is proposed based on these spectra and comparison with spectra of derivatives of pyruvic acid.The spectra of pyruvic acid can best be interpreted in terms of a cyclic hydrogen-bonded dimer structure in which the two carbonyl groups are in a trans configuration in the pure liquid phase. A similar structure has been reported for crystalline pyruvic acid by X-ray diffraction. In dilute solution the structure appears to be monomeric with an internal hydrogen bond, in essential agreement with the structures of the monomer reported from microwave spectroscopic measurements.     

Amide-ligand hydrogen bonding in reverse micelles

One approach to modeling the second coordination shell of metalloproteins is to pair amide-containing counterions with metal complexes to form hydrogen bonds in the solid state. In a more general approach, we have designed a surfactant counterion that can sustain hydrogen bonding interactions with metal complexes in solution. The surfactant is cationic and incorporates an amide as part of its headgroup to form hydrogen. The surfactant forms hydrogen bonding reverse micelles that accommodate anionic metal complexes in their polar core. In reverse micelles containing an iron(III) hexacyanide complex, spectroscopic evidence suggests that the anion is confined to the polar core region in solution. Single-crystal X-ray diffraction data on the surfactant ferricyanide system reveals a layered structure with interdigitated alkyl chains and an extensive network of hydrogen bonds that link amide groups to the cyanide ligands and to neighboring headgroups.     

Vibrations and hydrogen bonding in porphycene

Combined use of IR, Raman, neutron scattering and fluorescence measurements for porphycene isolated in helium nanodroplets, supersonic jet and cryogenic matrices, as well as for solid and liquid solutions, resulted in the assignments of almost all of 108 fundamental vibrations. The puzzling feature of porphycene is the apparent lack of the N-H stretching band in the IR spectrum, predicted to be the strongest of all bands by standard harmonic calculations. Theoretical modeling of the IR spectra, based on ab initio molecular dynamics simulations, reveals that the N-H stretching mode should appear as an extremely broad band in the 2250-3000 cm(-1) region. Coupling of the N-H stretching vibration to other modes is discussed in the context of multidimensional character of intramolecular double hydrogen transfer in porphycene. The analysis can be generalized to other strongly hydrogen-bonded systems.     

Chemical bonding in the hydrogen molecule

The chemical bond in the hydrogen molecule is examined using the electron density and the generalized overlap amplitudes. Logarithmic derivatives of the electron density provide a clear picture of its behavior in the bonding region as well as in the outer region. The GOA expansion of the density is used to examine the dependence of the rate of decay of the density on the GOA ionization potentials. The increase in the electron density at the nuclei and in the bonding region coincides with the higher ionization potential of H₂ over the H atom. The density in the bonding region along the internuclear axis does not decay exponentially, but its shape is very nearly an inverted Gaussian. © 1996 John Wiley & Sons, Inc.