三乙胺与2-氯-5-甲氧基对苯醌光电子转移反应的CIDNP研究

用化学诱导动态核极化（CIDNP）方法研究了三乙胺与2-氯-5-甲氧基对苯醌在 C6D6，CH3CN溶剂中的反应机理，实验结果表明反应过程中首先形成基态电荷转移 络合物（CTC），在CD3CN中，光照电荷分离形成离子自由基对，使三乙胺亚甲基产 生发射极化信号。同时用UV-vis实验证实CTC的存在。     

酰基吡唑啉酮双席夫碱配合物的电子结构、成键性与生物活性

The electronic structures of N,N′-bis[(1-phenyl-3-methyl-5-oxo-4-pyrazolinyl) α-furylmethylidyne]ethylendii- mine (and -o-phenylendiimine), and their complexes of transition metals M (M=Ni, Cu, Co, Pd, Pt) have been calculated by B3LYP method of DFT. Their geometries and bonding characters are discussed, and the relationship between their bioactivities and electronic structures are also discussed from the calculated results of electronic populations and frontier orbital energies.     

壳寡糖与镧、铈配合物的合成、表征及应用

合成了壳寡糖，镧和壳寡糖，铈配合物，用红外光谱和紫外光谱进行了表征，并证实了氮，金属(N-M)键的形成，元素分析证实配合物中各元素C：H：N：La或Ce的原子个数比分别接近于24：44：4：1，即相当于配位数为4。壳寡糖一镧和壳寡糖一铈较未配位的镧或铈具有更强的催化氧化能力。配合物除去废液中磷[(PO)^3-4]的效果比未配位的镧和铈提高10％。配合物可提高蔬菜、水稻种子的发芽率，促进作物的营养生长，提高水稻产量3，3％，提高黄瓜产量12％～15％，对十字花科蔬菜的病毒有一定的抑制作用。     

二氯四(苯丙酮-1, 2, 4-三唑)合钴六水配合物晶体结构

0IntroductionRecently,thecompoundscontaining1H-1,2,4-tr-iazolegrouphaveattractedmuchinterestbecauseoftheirexhibitingsomefungicidalactivityandplantgrowthregulatingactivity犤1犦,andshowingantibacterialactivityagainstPucciniareconditeandrootsgrowthregulationforcucumber犤2犦.Also,suchcompoundsareincreasinglybeingstudiedbecauseofthecoordinationchemistryofazolesactingasligandsintransitionmetalcompounds.Asamatteroffact,thetriazolederivativeshavebeenextensivelyusedasterminalandbridgingligands,andthey…     

二(三苯基膦)水杨酸铜(Ⅰ)乙醇溶剂配合物的晶体结构

0IntroductionThestudyofcopper?complexesisinvestigatedinmanylaboratories.Amongthereasonsforcarryingouttheinvestigationofsuchspeciesaretheirstructuralfeatures犤1犦,theusefulnessofcopper?compoundsinorganicsyntheses犤2犦andthewell-documentedimpor-tanceofcopper?centersattheactivesitesofanumberofprotein犤3犦.Concerningcopper?carboxy-latesafurtherinterestexists,stemmingfromtheiruseinhomogeheouscatalysedhydrogenation犤4犦.Thecopper?bis(triphenylphosphine)cationisasoft,butflexi-bleacceptorionthatcanacc…     

Stability and structure of mixed-ligand metal ion complexes that contain Ni2+, Cu2+, or Zn2+, and Histamine, as well as adenosine 5'-triphosphate (ATP4-) or uridine 5'-triphosphate (UTP(4-): an intricate network of equilibria

With a view on protein–nucleic acid interactions in the presence of metal ions we studied the “simple” mixed‐ligand model systems containing histamine (Ha), the metal ions Ni²⁺, Cu²⁺, or Zn²⁺ (M²⁺), and the nucleotides adenosine 5′‐triphosphate (ATP^4?) or uridine 5′‐triphosphate (UTP^4?), which will both be referred to as nucleoside 5′‐triphosphate (NTP^4?) . The stability constants of the ternary M(NTP)(Ha)^2? complexes were determined in aqueous solution by potentiometric pH titrations. We show for both ternary‐complex types, M(ATP)(Ha)^2? and M(UTP)(Ha)^2?, that intramolecular stacking between the nucleobase and the imidazole residue occurs and that the stacking intensity is approximately the same for a given M²⁺ in both types of complexes: The formation degree of the intramolecular stacks is estimated to be 20 to 50 %. Consequently, in protein–nucleic acid interactions imidazole–nucleobase stacks may well be of relevance. Furthermore, the well‐known formation of macrochelates in binary M²⁺ complexes of purine nucleotides, that is, the phosphate‐coordinated M²⁺ interacts with N7, is confirmed for the M(ATP)^2? complexes. It is concluded that upon formation of the mixed‐ligand complexes the M²⁺? N7 bond is broken and the energy needed for this process corresponds to the stability differences determined for the M(UTP)(Ha)^2? and M(ATP)(Ha)^2? complexes. It is, therefore, possible to calculate from these stability differences of the ternary complexes the formation degrees of the binary macrochelates: The closed forms amount to (65±10) %, (75±8) %, and (31±14) % for Ni(ATP)^2?, Cu(ATP)^2?, and Zn(ATP)^2?, respectively, and these percentages agree excellently with previous results obtained by different methods, confirming thus the internal validity of the data and the arguments used in the evaluation processes. Based on the overall results it is suggested that M(ATP)^2? species, when bound to an enzyme, may exist in a closed macrochelated form only, if no enzyme groups coordinate directly to the metal ion.     

环硅氮烷的合成与应用研究进展(1)——环二硅氮烷

环二硅氮烷是有机硅氮化合物中结构与性能比较特殊的一类化合物,在材料化学及配位化学领域有重要的潜在应用前景.综述了近年来环二硅氮烷的合成方法与应用研究进展.在合成方面,主要分为3条路线,分别由环三硅氮烷锂盐、取代硅胺及六氯化二硅为起始物.在应用领域,介绍了环二硅氮烷的离子开环聚合、等离子聚合、与其它单体的共聚、水解和金属配合物的制备及其在陶瓷、粘合剂和预想的催化剂上的应用.     

3,5-二硝基水杨酸铕/聚合物的合成及光致发光性能

合成了3,5-二硝基水杨酸铕配合物(EuDNS)及其聚合物材料,通过元素分析和红外光谱等测试技术推测了配合物的结构,考察了配合物的用量和聚合物基质对聚合物材料荧光性能的影响。 结果表明,配合物EuDNS可能存在的螯合杂环结构使其有较宽的紫外吸收,且与其荧光激发波长能较好的吻合,能发射很强的稀土Eu3+离子特征红光;当EuDNS质量分数为0.25%时,EuDNS/PMMA（甲基丙烯酸甲酯）聚合物材料仍有很强的荧光强度;3种不同聚合物基质中,最强发射峰强度顺序为:P(MMA-co-St)＞PMMA＞P(MMA-co-AA),丙烯酸（AA）共聚单体会强烈猝灭材料发光;EuDNS对MMA/St自由基共聚有阻聚和缓聚作用,随苯乙烯（St）的比例提高,阻聚作用增大,且材料透明性降低;与EuDNS配合物相比,EuDNS/PMMA聚合物材料形成后表观荧光寿命延长了467.5 μs。     

Substituted Quinolinones. Part 19. New and Unexpected Results from Oxidation of 3-Acetyl-1-Alkyl- 4-Hydroxyquinolin-2(1H)-Ones Using Selenium Dioxide

Abstract

Oxidation of 3-acetyl-1-alkyl-4-hydroxyquinolin-2(1H)-ones using selenium dioxide under Riley conditions was described. The oxidation reaction produced a mixture of 2 unexpected α-keto acid and its dehydrated dimer derivatives. The oxidation reaction was studied under different reaction conditions in order to maximize the yields and optimize reaction conditions. Also, 1-alkyl-4-hydroxy-3-(2-nitroacetyl)quinolin-2(1H)-one and/or 3-acetyl-1-alkyl-4-diflouro-boryloxyquinolin-2(1H)-one derivatives were subjected to the same oxidation reaction giving rise improved reaction yields and selectivity in case of the boron-complex. Alkaline degradation of the dehydrated dimers led to formation of the 4-hydroxy-2-oxoquinoline-3-carboxylic acids while under the same conditions the α-keto acids underwent deoxalylation.

[Supplemental materials are available for this article. Go to the publisher's online edition of Phosphorus, Sulfur, and Silicon and the Related Elements to view the following free supplemental files: Additional figures].     

The First Rotational Isomers of Stable Selenobenzaldehydes and their η1-Tungsten Complexes

The first rotational isomers of stable selenoaldehydes are synthesized by deselenation of cyclic polyselenides having an efficient steric protection group, 2, 4, 6-tris[bis(trimetylsilyl)methyl]phenyl (Tbt). Reactions of these selenoaldehydes with W(CO)₅.THF gives the corresponding η¹-selenoaldehyde tungsten complexes, the structures of which are established by X-ray crystallography.