(NH_2CH_2CH_2NH_3)_4[W~ⅤO_2(OC_6H_4O)_2]_2(NH_3CH_2CH_2NH_3)·H_2O的合成、晶体结构、EPR以及与同构物的比较

在很多生物代谢过程中,微量元素W起着关键作用,W与生物大分子结合形成具有特异功能的钨氧转移酶。1983年从热醋酸菌中提取了第一种钨酶,即甲酸脱氢酶,目前从生物体内提取的钨酶种类已达十二种之多,并发现钨氧转移酶与钼氧转移酶的活性结构因子呈相近性[1]。随着钨酶在生物体内的作用逐步得到重视,及其模拟的功能配合物在探究钨酶的生理活性和催化机理研究中所作的突出贡献,使钨氧转移酶活性结构因子的仿生合成、生理活性以及催化机理研究成为研究热点[2￣14]。根据报道显示,单分子的钨氧模拟配合物中W的价态只有WⅣ、WⅥ两种,且形成一个电…     

钨酶的研究进展

本文对钨酶的发现历史、生理作用以及功能配合物的模拟研究进行了综述,共引用文献23篇.     

生物无机化学的新台阶

作为生命化学的重要组成部分,生物无机化学开始进入成熟发展阶段。这首先表现在它所研究的覆盖面迅速扩展。除了在金属蛋白和金属酶方面由铁、铜、锌、钴……等扩大到诸如镍酶、钒酶、锰酶、钼酶、钨酶……等以外,还从金属蛋白扩大到以非金属元素为活性元素的蛋白,如硒     

多酸含量对无机/高分子复合薄膜结构及光致变色性能的影响

制备了一系列不同浓度的钨磷酸/聚乙烯醇(PWA/PVA)复合薄膜, 通过红外光谱、原子力显微镜、紫外-可见吸收光谱对复合薄膜的结构和光致变色性能进行了研究. 红外光谱分析结果表明, Keggin结构钨磷酸和聚乙烯醇分子的基本结构在复合薄膜中仍然存在, 钨磷酸分子与高分子底物间存在氢键作用, 形成电荷转移桥. 原子力显微镜(AFM)结果表明复合前后PVA薄膜表面形貌发生了显著变化, 复合膜表面形貌随钨磷酸含量的不同而不同. 在紫外光照射下, 复合薄膜由无色变为蓝色. 复合膜的升色速度和褪色速度均随着钨磷酸含量的增加而加快. 这些结果表明钨磷酸含量对复合膜的微结构存在影响, 从而导致了复合膜具有不同的光致变色性能.     

钨的化学机械抛光过程中TiN-W电偶的腐蚀行为(英文)

化学机械抛光 (CMP)技术是同时利用化学和机械作用来获得固体表面亚微米尺度上平整性非常有效的方法 ,从 90年代初期起已成为制备高质量镜头和镜面及集成电路制造过程中硅片表面预处理工艺中最常用的技术之一 .钨的化学机械抛光是用钨坯获得硅片球面平整度的重要工艺 .其过程实际上是先将钨沉积到硅上已有的薄粘附层 -氮化钛上 ,然后进行化学机械抛光 .当抛光阶段接近终了时 ,氮化钛和钨表面将同时暴露在化学抛光液中形成电偶对 ,并在界面上发生腐蚀行为 ,从而影响硅片的球面平整度 ,降低半导体器件的性能与可靠性 .本文通过采用电化学直流极化技术 ,分别获得钨与氮化钛在 0 .0 1mol/LKNO3溶液中或含有三种典型的研磨剂 (H2 O2 ,KIO3,Fe(NO3) 3)溶液中的极化曲线 ,同时设计了一种特殊的电解槽以测量钨和氮化钛之间相互作用的电流 ,初步研究了 patterned硅片上钨和氮化钛界面形成电偶对时的腐蚀行为 .根据所测的钨和氮化钛电位可知 ,当钨和氮化钛表面同时暴露在抛光液中时将形成电偶对 ,氮化钛成为阴极 ,钨为阳极 ,并于界面发生电化学反应 ,表面的不均匀腐蚀将造成硅片平整度的降低 .结果表明 ,当溶液中含有H2 O2 时钨和氮化钛界面的腐蚀速度最大 ,而当溶液中含有Fe(NO3) 3时的钨和氮化钛界面则几乎不发     

纳米钨合金块体材料的制备

高比重钨合金由于具有一系列优异的物理力学性能, 因此在航空航天、国防军工和民用中有着广泛的应用前景.采用纳米技术制备高比重钨合金块体材料有望进一步提高其性能, 促使其应用.本文分析了纳米钨合金在粉末制备和成型烧结中存在的问题, 并针对纳米钨合金粉末成型和烧结过程中晶粒长大问题以及块体材料中存在大量微孔问题, 介绍了数种可行性控制方法.     

W-SBA-15介孔分子筛的直接合成及其对环己烯环氧化反应的催化性能

 分别以Na2WO4和H2WO4为钨源,以正硅酸四乙酯为硅源直接合成了W-SBA-15介孔分子筛样品,并用小角XRD,N2吸附,FT-IR,UV-Vis,SEM和XRF等手段对合成的分子筛进行了表征. 结果表明,只用P123(EO20PO70EO20)为模板剂时,分子筛中钨的含量只是投料量的一半; 而以P123和十六烷基三甲基溴化铵为混合模板剂时,钨能有效地掺杂到SBA-15分子筛中. 当原料中的Si/W摩尔比为40时,W-SBA-15分子筛中的钨物种以高度分散状态存在,且以H2WO4为钨源比以Na2WO4为钨源更易将钨掺杂到SBA-15介孔分子筛中. W-SBA-15分子筛催化剂对环己烯环氧化反应具有较高的催化活性.     

钨(Ⅵ)-水杨基荧光酮-溴化十六烷基吡啶三元络合物光度法测定微量钨

利用水杨基荧光酮(SAF)、阳离子表面活性剂溴化十六烷基吡啶(CPB)与钨(Ⅵ)形成三元络合物,建立了测定微量钨的光度分析方法.该络合物的最大吸收波长为520 nm,表观摩尔吸光系数ε520=1.22×105 L/(mol·cm),钨的浓度在0～10 μg/25 mL范围内服从比尔定律,钨(Ⅵ)的回收率为96.0%～102.4%,测定的标准偏差为0.24.该法可用于矿物和合金钢中钨的测定.     

钼和钨在氧化铝表面的分散特性

以低温(873 K)和高温(1173 K)焙烧的氧化铝为载体制备了一系列负载钼和/或钨催化剂,结合X射线衍射、红外光谱、氨溶实验、氢气程序升温还原表征以及 4,6-二甲基二苯并噻吩加氢脱硫性能评价,研究了钼和钨在氧化铝表面分散的特性. 结果发现,钼倾向与碱性羟基和中性羟基作用,而钨优先与中性羟基作用. 钼的引入促进了钨的还原. 氨溶后残余的钼钨物种虽然与载体的作用较强,但经焙烧后它们在载体表面重新再分散,达到新的热力学或能量平衡.     

高含量钨的氧化还原滴定法

多年来,建立快速、准确的高含量钨的分析方法是国内外分析工作者研究的重要课题.据报道,差示分光光度法,虽然快速,但操作要求严格,且需用精密仪器;络合滴定法和酸碱中和法,则影响因素较多;氧化还原法由于钨的易变价特性,往往难以把它还原或氧化至某一固定价态并保持稳定.本文提出在硫氰酸盐介质下用铅粒或银粉将钨(Ⅵ)定量还原为钨(Ⅴ),然后用标准铁(Ⅲ)溶液滴定钨(Ⅴ)的新方法,由于钨(Ⅴ)酰硫氰酸络合物在空气中很稳定,测定获得良好效果.方法快速、准确、干扰少,用于测定矿物中高含量的钨,结果与硝酸铵重量法一致.     

X-ray spectroscopy of enzyme active site analogues and related molecules: bis(dithiolene)molybdenum(IV) and -tungsten(IV,VI) complexes with variant terminal ligands

The X-ray absorption spectra at the molybdenum and selenium K-edges and the tungsten L2,3-edges are acquired for a set of 14 Mo(IV) and W(IV,VI) bis(dithiolene) complexes related to the active sites of molybdo- and tungstoenzymes. The set includes square pyramidal [MoIVL(S2C2Me2)2]- (L = O2-, R3SiO-, RO-, RS-, RSe-) and [WIV(OR)(S2C2Me2)2]-, distorted trigonal prismatic [MoIV(CO)(SeR)(S2C2Me2)2]- and [WIV(CO)L(S2C2Me2)2]- (L = RS-, RSe-), and distorted octahedral [WVIO(OR)(S2C2Me2)2]-. The dithiolene simulates the pterin-dithiolene cofactor ligand, and L represents a protein ligand. Bond lengths are determined by EXAFS analysis using the GNXAS protocol. Normalized edge spectra, non-phase-shift-corrected Fourier transforms, and EXAFS data and fits are presented. Bond lengths determined by EXAFS and X-ray crystallography agree to < or = 0.02 A as do the M-Se distances determined by both metal and selenium EXAFS. The complexes [MoIV(QR)(S2C2Me2)2]- simulate protein ligation by the DMSO reductase family of enzymes, including DMSO reductase itself (Q = O), dissimilatory nitrate reductase (Q = S), and formate dehydrogenase (Q = Se). Edge shifts of these complexes correlate with the ligand electronegativities. Terminal ligand binding is clearly distinguished in the presence of four Mo-S(dithiolene) interactions. Similarly, five-coordinate [ML(S2C2Me2)2]- and six-coordinate [M(CO)L(S2C2Me2)2]- are distinguishable by edge and EXAFS spectra. This study expands a previous XAS investigation of bis(dithiolene)metal(IV,V,VI) complexes (Musgrave, K. B.; Donahue, J. P.; Lorber, C.; Holm, R. H.; Hedman, B.; Hodgson, K. O. J. Am. Chem. Soc. 1999, 121, 10297) by including a larger inventory of molecules with variant physiologically relevant terminal ligation. The previous and present XAS results should prove useful in characterizing and refining metric features and structures of enzyme sites.     

Substitution and oxidation reactions of bis(dithiolene)tungsten complexes of potential relevance to enzyme sites

Structurally characterized tungstoenzymes contain mononuclear active sites in which tungsten is coordinated by two pterin-dithiolene ligands and one or two additional ligands that have not been identified. In this and prior investigations (Sung, K.-M.; Holm, R. H. Inorg. Chem. 2000, 39, 1275; J. Am. Chem. Soc. 2001, 123, 1931), stable coordination units of bis(dithiolene)tungsten(IV,V,VI) complexes potentially related to enzyme sites have been sought by exploratory synthesis. In this work, additional members of the sets [WL(S2C2Me2)2](2-,-) and [WLL'(S2C2Me2)2](2-,-) have been prepared and structurally characterized. Tungsten(IV) complexes obtained by substitution are carbonyl displacement products of [W(CO)2(S2C2Me2)2] and include those with the groups W(IV)S (4), W(IV)(O2CPh) (5), and W(IV)(2-AdQ)(CO) (Q = S (6), Se (7); Ad = adamantyl). Those obtained by oxidation reactions contain the groups W(V)O (9), W(V)(QPh)2 (Q = S (10), Se (11)), W(VI)S(OPh) (12), and W(VI)O2 (14). The latter two complexes were obtained from W(IV) precursors using sulfur and oxygen atom transfer reactions, respectively. Complexes 4 and 9 are square pyramidal; 6, 7, 10, and 11 are distorted trigonal prismatic with cis ligands LL'; and 12 and 14 are distorted octahedral. Complexes 4, 10, and 11 support three-membered electron transfer series. Attempts to oxidize 4 to the W(V)S complex results in the formation of binuclear [W2(mu2-S)2(S2C2Me2)4](2-) having distorted octahedral coordination. The 21 known functional groups WL and WLL' in mononuclear bis(dithiolene) complexes prepared in this and prior investigations are tabulated. Of those with physiological-type ligands, it remains to be seen which (if any) of these ligation modes are displayed by enzyme sites.     

Oxo/sulfidotungstate(VI) as precursors to W(VI)O2, W(VI)OS, and W(VI)S2 complexes and W(IV)-dithiolene chelate rings

Synthetic models leading to oxosulfidotungsten(VI) groups and dithiolene chelate rings have been investigated. The heterogeneous reaction systems [WO4-nSn]2-/2Ph3SiCl/Me4phen (n = 0-2) in acetonitrile afford the complexes [WQ2(OSiPh3)2(Me4phen)] (1-3) in the indicated yields containing the groups W(VI)O2 (1; 86%), W(VI)O2 (2; 45%), and W(VI)S2 (3; 83%). In the crystalline state these complexes have imposed C2 symmetry, with cis-oxo/sulfido and trans-silyloxide ligands. 1H NMR spectra indicate that this stereochemistry is retained in solution. The colors of 2 (yellow, 367 nm) and 3 (orange, 451 nm) arise from LMCT absorptions at the indicated wavelengths. These results demonstrate that the silylation procedure previously introduced for the preparation of molecules with the Mo(VI)OS group (Thapper, et al. Inorg. Chem. 1999, 38, 4104) extends to tungsten. Methods for the formation of dithiolene chelate rings MS2C2R2 in reactions with sulfide-bound M = Mo or W precursors are summarized. In a known reaction type, 3 and activated acetylenes rapidly form [W(IV)(OSiPh3)2(Me4phen)(S2C2R2)] (R = CO2Me, 4, 83%, and Ph, 5, 98%). In a new reaction type not requiring the isolation of an intermediate, the systems [MO2S2]2-/2Ph3SiCl/Me4phen/PhC=CPh in acetonitrile afford 5 (68%) and [Mo(IV)(OSiPh3)2(Me4phen)(S2C2Ph2)] (6; 61%). Complexes 5 and 6 are isostructural, maintain the trans-silyloxide stereochemistry, and exhibit chelate ring dimensions indicative of ene- 1,2-dithiolate coordination. Reductions in the -1.4 to -1.7 V range are described as metal-centered. It remains to be seen whether the oxo/sulfidotungsten(VI) groups in 1-3 eventuate in the active sites of tungstoenzymes. (Me4phen = 3,4,7,8-tetramethyl-1,10-phenanthroline.)     

Nucleophilic reactivity and oxo/sulfido substitution reactions of MVIO3 Groups (M = Mo, W)

The nucleophilic reactivity of oxo ligands in the groups M(VI)O(3) in the trigonal complexes [(Me(3)tacn)MO(3)] (M = Mo (1), W (10)) and [(Bu(t)(3)tach)MO(3)] (M = Mo (5), W (14)) has been investigated. Complexes 1/10 can be alkylated with MeOTf to give [(Me(3)tacn)MO(2)(OMe)](1+) (2/11), silylated with Pr(i)(3)SiOTf to form [(Me(3)tacn)MO(2)(OSiPr(i)(3))](+) (3/12), and protonated with HOTf to yield [(Me(3)tacn)MoO(2)(OH)](+) (4). Similarly, complexes 5/14 can be silylated to [(Bu(t)(3)tach)MO(2)(OSiPr(i)(3))](+) (6/15) and protonated to [(Bu(t)(3)tach)MO(2)(OH)](+) (7/16). Products were isolated as triflate salts in yields exceeding 70%. When excess acid was used, the dinuclear mu-oxo species [(Bu(t)(3)tach)(2)M(2)O(5)](2+) (8/17) were obtained. X-ray structures are reported for 2-4, 6-8, 12, and 15-17. All mononuclear complexes have dominant trigonal symmetry with a rhombic distortion owing to a M[bond]OR bond (R = Me, SiPr(i)(3), H), which is longer than M[double bond]O oxo interactions; the latter exert a substantial trans influence on M[bond]N bond lengths. Oxo ligands in 5/14 undergo replacement with sulfide. Lawesson's reagent effects formation of [(Bu(t)(3)tach)MS(3)] (9/18), 14 with excess B(2)S(3) yields incompletely substituted [(Bu(t)(3)tach)WOS(2)] (20), and 5 with excess B(2)S(3) yields [(Bu(t)(3)tach)Mo(IV)O(S(4))] (19). The structures of 9, 19, and 20 are reported. Precedents for M(VI)S(3) groups in five- and six-coordinate molecules are limited. This investigation is the first detailed study of the behavior of M(VI)O(3) groups in nucleophilic and oxo/sulfido substitution reactions and should be useful in synthetic approaches to the active sites of the xanthine oxidase enzyme family and of certain tungstoenzymes. (Bu(t)(3)tach = 1,3,5-tri-tert-butyl-1,3,5-triazacyclohexane, Me(3)tacn = 1,4,7-trimethyl-1,4,7-triazacyclonane; OTf = triflate).     

An expanded set of functional groups in bis(dithiolene)tungsten(IV,VI) complexes related to the active sites of tungstoenzymes, Including WIV-SR and WVI-O(SR)

The active sites of tungstoenzymes have the formulations W(IV,V)L(S(2)pd)(2) and W(VI)LL'(S(2)pd)(2), in which two pyranopterindithiolene cofactor ligands (S(2)pd) are chelated to a tungsten atom. Ligands L and/or L' are not fully defined in any wild-type enzyme. The feasibility of various coordination fragments (functional groups) in potential bis(dithiolene)tungsten site analogues has been examined in previous work by exploratory synthesis. This investigation expands the range of accessible functional groups. The synthetic scheme originates with [W(CO)(2)(S(2)C(2)Me(2))(2)], whose carbonyl groups are labile to substitution. Complexes [W(IV,VI)LL'(S(2)C(2)Me(2))(2)](1-) are described in terms of their functional groups W(IV,VI)LL'. Reaction of the dicarbonyl with formate in acetonitrile/THF affords W(IV)(CO)(eta(1)-HCO(2)) (4) and in Me(2)SO W(VI)O(eta(1)-HCO(2)) (7) by an oxo transfer reaction. Carboxylates yield six-coordinate W(IV)(eta(2)-O(2)CR) (1-3, R = Ph, Me, Bu(t)) with C(2)(v) symmetry. Reaction of 3 (R = Bu(t)) with Me(3)SiSR (R = C(6)H(2)-2,4,6-Pr(i)(3)) gives W(IV)(SR) (5), which undergoes oxo and sulfido atom transfer to form W(VI)O(SR) (8) and W(VI)S(SR) (9), respectively. Attempts to prepare corresponding selenolate complexes, pertinent to the active site of formate dehydrogenase, were unsuccessful, including reactions of W(VI)OCl (10) with RSe(-). Structure proofs of 2-10 were obtained by X-ray structure determinations. Some 26 functional group types in bis(dithiolene)W(IV,V,VI) molecules have now been achieved by synthesis. It remains to be seen which are incorporated in an enzyme site. A number of them (e.g., 5) are directly analogous to molybdoenzyme sites, and may possess corresponding reactivity with biological substrates, as do W(IV)(OR)/W(VI)O(OR) (prepared earlier) in the reduction of N- and S-oxides by atom transfer.     

离聚体水基微乳液化的研究——聚苯乙烯离聚体微乳化过程相反转的表征

以乙酰磺酸为磺化剂制备磺化度为３～１５ｍｏｌ％的磺化聚苯乙烯（ＳＰＳ）并中和成盐．在一定的温度和搅拌速率下，加水将ＳＰＳ乳化成水包油的稳定水基微乳液．用乳化过程中体系电导率和粘度的变化表征了乳化相反转过程．研究了溶剂的极性和离子含量对聚苯乙烯离聚体溶液可乳化性和乳化过程及乳液稳定性的影响．     

N-异丙基丙烯酰胺/丙烯酸十八酯共聚物水溶液胶束及相分离行为研究

合成了N异丙基丙烯酰胺(NIPAM)和丙烯酸十八酯(ODA)的共聚物.利用荧光探针和滴重法研究了NIPAMODA共聚物在水溶液中的胶束形成过程.同时还利用荧光探针法研究了共聚物水溶液在温度升高时出现的LCST(LowerCriticalSolutionTemperature)现象,表明该高分子在温度升高时存在着相分离现象.利用LB技术测量共聚物不溶单分子膜的PA曲线,发现随着温度升高共聚物的单分子膜越来越凝聚的反常现象,这从另一个侧面证实了共聚物NIPAMODA的相分离行为,并对此现象作了讨论.     

2.45GHz下常用有机试剂复介电常数的测量与研究

1986年加拿大的R．Gedye和R．J．Giguere等发现了微波可以显著加快有机合成,他们发现用微波辐射可使反应速率和产率有不同程度的提高。由于微波作用机理的特殊性,微波化学对很多化学领域带来了冲击。但是,微波与化学反应体系之间相互作用的一些重大问题还未得到解决,如微波加热过程中化学反应系统的非线性反射、非均匀加热等。解决这类问题,首先必须了解化学反应过程中混合物的电学性质与磁学性质,而物质的宏观电学和磁学性质都用其介电常数和磁导率来描述。对于大部分是非磁性材料的有机试剂,微波与反应体系相互作用的特性集中体现在体系的等效复介电常数上。了解各种常用试剂的复介电常数,可以进一步了解各种化学试剂对微波的吸收和反射的情况。而很多试剂的复介电常数无法从现有文献中得到。本文利用谐振腔微扰法测定了在2．45GHz室温下各类常用有机试剂的复介电常数,结果显示：醇类试剂复介电常数实部与虚部都较大;酮类试剂复介电常数实部相对较大,而虚部较小;酸类试剂复介电常数实部和虚部都较小;烷烃和苯类试剂实部,虚部更小。同时,随着碳链增加,所有试剂的复介电常数的实部与虚部均有下降趋势。这些测试和分析结果将为微波辅助有机合成提供了有益参考。     

渣油在加氢处理中的性质和结构变化规律研究

利用渣油加氢处理中试装置,获得了经过脱金属催化剂、脱硫催化剂和脱氮催化剂的系列渣油加氢处理产物,分析了各产物的性质。随加氢深度增加,硫、氮、残炭、镍和钒在渣油加氢产物中的的质量分数降低,总脱除率分别为84.9%、51.3%、62.8%、84.8%和94.0%。各产物的组分分布发生变化,饱和分组分增加,芳香分、胶质、沥青质组分减少,重组分胶质和沥青质组分的转化分别达到了57.5%和73.3%。以核磁共振为基础计算了渣油加氢产物组分的平均结构参数。结果表明,芳香分和胶质组分单元结构芳香环数和环烷环数减少,芳香碳分率fA、环烷碳分率fN和烷基碳分率fP变化不明显;而沥青质分子fA增加,fN和fP降低。从平均结构参数还可以看出,不同加氢产物同一种组分在结构上有其共性,但不同组分有明显区别。