单茂钪催化剂（C5H5）Sc（CH2C6H4NMe2-o）2合成高顺式窄分布聚丁二烯

合成了6种单茂稀土催化剂Cp’LnR2(THF)n(其中,Cp’=C5H5,C5Me4SiMe3;R=CH2C6H4NMe2-o,CH2SiMe3;Ln=Sc,Y,Lu;n=0或1),并以[Ph3C][B(C6F5)4]为助催化剂,甲苯为溶剂,考察催化剂结构对丁二烯聚合活性,立体选择性,催化剂利用率以及聚合物分子量和分子量分布的影响.通过1H-NMR,13C-NMR,FTIR,GPC以及DSC对聚丁二烯进行表征,结果表明,当Cp’=C5H5,R=CH2C6H4NMe2-o,Ln=Sc,n=0时,催化剂(C5H5)Sc(CH2C6H4NMe2-o)2对丁二烯聚合活性最高,可达9600 kg-polymer/mol-Sc·h,催化剂利用率为45%,聚丁二烯顺-1,4结构含量在96%~98%之间,分子量分布窄,指数在1.3左右;以甲苯或氯苯作为聚合溶剂时,聚合活性最高,聚丁二烯分子量保持窄分布,在所有溶剂中聚丁二烯顺-1,4结构含量均达到96%以上;催化剂聚合活性随温度下降而降低,而聚合物分子量分布有变窄的趋势,温度对聚丁二烯立体选择性无明显影响;当[Bd]/[Sc]摩尔比从500增加到3000时,聚合反应1 min转化率均达到100%,聚丁二烯分子量呈可控线性增大,最高达44.6×104,且均保持聚合物窄分布.DSC谱图表明聚丁二烯Tg为-107℃,当升降温速率为10 K/min时,在-63℃和-8℃附近呈现出明显的冷结晶峰和熔融峰.     

Ni(naph)_2/A1R_3/BF_3·OEt_2/DMEA/OctOH体系催化丁二烯配位聚合

在Ni(naph)2-AlR3-(BF3·OEt2)催化体系(简称Ni-Al-B)用于丁二烯(Bd)/己烷进行配位聚合体系中引入N,N-二甲基乙醇胺(DMEA)和辛醇(OctOH),研究了DMEA/Ni摩尔比、B/Ni摩尔比和Al/Ni摩尔比对Bd聚合转化率、聚丁二烯(PB)产物的特性黏数、分子量、分子量分布及微观结构的影响,进一步探讨聚合反应动力学.结果表明,在镍系催化丁二烯聚合体系中引入一定量的DMEA和OctOH后,可以提高顺-1,4微观结构含量至97.8%,降低1,2-微观结构含量至约1.3%,提高分子量,使分子量分布变窄,并降低凝胶含量.进一步通过调节B/Ni及Al/Ni摩尔比值,可得到[η]为2.0～4.0dL/g的高顺式PB.聚合速率对单体浓度呈现一级动力学关系,表观增长活化能为43.7kJ·mol-1。     

用可溶性催化剂合成顺式聚丁二烯的研究——Ⅰ.用CoCl2·4C5H5N-(C2H5)2AlCl作催化剂

本文研究了催化剂的用量、单体的浓度、聚合温度等聚合条件对聚丁二烯的转化率、分子量以及链结构的影响。试验结果表明:这个催化剂的特点是催化剂用量极少,1,4-顺式含量高而且稳定,聚合速度太快,高聚物的分子量过大,因此进一步研究了聚合速度的控制和高聚物分子量的调节。已得到的结果是:(1)在不同溶剂中聚合的速度相差甚大。其快慢的顺序是,苯>甲苯>二甲苯>三甲苯。(2)添加一些如苯基-β-萘胺、N,N′-二苯基对苯二胺等胺类,既可减慢聚合速度,又能降低高聚物的分子量。(3)调节体系中水分的含量,控制高聚物的分子量。(4)利用二种溶剂混合的不同比例,调节高聚物的分子量。(5)加入少量的萘、蒽等稠环芳烃于庚烷溶剂中,则大大提高高聚物的分子量。对上述结果进行了讨论。     

配合物Fe(pda)2(H2O)4和[FeCo(pda)4(H2O)4]n的合成与晶体结构

采用水热法合成了2个3-(3-吡啶基)丙烯酸的配合物:Fe(pda)2(H2O)4(1)和[FeCo(pda)4(H2O)4]n(2)(pda=3-(3-吡啶基)丙烯酸),用红外光谱、元素分析、热重-差热以及X-射线衍射单晶结构分析进行了表征.2个配合物都属于单斜晶系,配合物1的空间群为P21/n,配合物2的为P21/c.配合物1是一个pda配体中仅吡啶基氮原子参与配位、而羧基上的氧原子未参与配位的单核结构,通过大量的氢键作用形成三维超分子体系.2是pda配体桥联Fe和Co的异核二维层状配位聚合物;配体吡啶基上的氮原子和羧基上的氧原子都参与了配位,其中羧基采用单齿配位模式.     

(CH3)3C+NO2反应机理的理论研究

用量子化学密度泛函方法,在B3LYP/6-31G*水平下研究了叔丁基自由基(CH3)3C和NO2气体的反应机理.研究表明,该反应是在单、三态势能面上的多通道反应.不同反应通道的产物不同,单态下反应更容易发生.常温下对于一个敞开体系(例如在大气当中),(CH3)3C自由基和NO2作用主要生成比较稳定的化合物(CH3)3CONO和(CH3)3CNO2.这对于消除大气污染起到一定的作用.     

Li3V2(PO4)3/C和Li2.5Na0.5V2(PO4)3/C的结构和电化学性能的比较研究

采用溶胶-凝胶法合成了锂离子正极材料Li3V2(PO4)3/C(LVP/C)及Li2.5Na0.5V2(PO4)3/C,并用XRD、循环伏安及交流阻抗等方法,研究了大量Na+掺杂对材料结构和电化学性能影响。结果表明,大量钠离子的掺杂会使LVP结构由单斜向菱方转变。掺杂化合物Li2.5Na0.5V2(PO4)3/C在0.5 C充电1 C放电时,首次放电容量为118 mAh.g-1,50次循环后容量保持率为92.4%,并发现与单斜LVP存在多个放电平台不同,Li2.5Na0.5V2(PO4)3/C仅在3.7 V处有一个放电平台。     

PANI/Ce(OH)3-Pr2O3·3H2O/NanoG复合材料制备与表征

开发了反胶束模板-原位聚合纳米复合法制备聚苯胺(PANI)/Ce(OH)3-Pr2O3·3H2O/石墨纳米薄片(NanoG)纳米复合材料的方法.膨胀石墨在乙醇水溶液中经超声处理制得石墨纳米薄片,以苯胺的氯仿溶液为油相,稀土金属离子Pr3+、Ce3+水溶液为水相,依靠表面活性剂十六烷基三甲基溴化铵(CTAB)自组装形成的反胶束为模板-制备PANI/Ge(OH)3-Pr2O3·3H2O/NanoG复合材料.利用红外光谱(FTIR)、扫描电镜(SEM)、透射电镜(TEM)和 X-射线衍射(XRD)对该复合材料进行了表征和分析,研究了其导电性能和热性能.结果表明,PANI/Ce(OH)3-Pr2O3·3H2O/NanoG复合材料各相分散均匀,稀土纳米粒子在体系中以棒状的形态分布.热重分析表明,该复合材料的热稳定性明显提高;导电性研究说明,石墨纳米薄片的特殊的结构(较大的径厚比)对其在聚合物基体中形成导电网络具有重要作用;PANI/Pr2O3-Ce(OH)3/NanoG纳米复合材料的渗滤阀值低于1.0wt%.     

吡啶双亚胺酰氯Ni(Ⅱ)配合物的合成、表征及催化合成液体聚丁二烯

合成了一系列吡啶双亚胺酰氯三齿Ni(Ⅱ)配合物(1a~1c,2a~2c),通过傅里叶变换红外光谱和元素分析对配合物进行表征,测定了配合物1a~1c的晶体结构.3个化合物同属于单斜晶系,且都具有以Ni原子为中心的近似于C s对称的扭曲三角双锥构型.该系列配合物通过倍半乙基氯化铝(EASC)活化,在20℃下对丁二烯聚合表现出良好的催化活性,得到分子量为4700~5200、cis-1,4含量为74.8%~77.2%(摩尔分数)的液体聚丁二烯.通过改变配体的结构和聚合条件,可在一定范围内调控聚丁二烯的结构和分子量.     

Mg(BO2)2在MgCl2水溶液中的相平衡与化学平衡

借助拉曼光谱和X射线衍射(XRD)检测手段,对Mg(BO_2)_2在MgCl_2水溶液中水解的固液相平衡与物种化学平衡规律进行了研究。结果表明,MgCl_2对Mg(BO_2)_2的溶解转化、多硼氧配阴离子的物种分布有很大影响:(1)随着MgCl_2浓度从0达到饱和,Mg(BO_2)_2的表观饱和浓度从0.79%增加到1.96%,pH值从9.96降到6.27;(2)Mg(BO_2)_2在纯水中水解形成固相Mg_2B_6O_(11)·15H_2O和Mg(OH)_2,在MgCl_2溶液中形成固相Mg_2B_6O_(11)·15H_2O和Mg_3Cl_2(OH)_4·4H_2O;(3)Mg(BO_2)_2在纯水中水解,硼的物种主要为B_4O_5(OH)_4~(2-)和B_3O_3(OH)_4~-,分别占液相总硼含量的49.81%和19.54%。在MgCl_2饱和溶液中,主要为B_3O_3(OH)_4~-和B_5O_6OH)_4~-,分别占液相总硼含量的44.57%和40.00%。     

以哌嗪为模板剂的二维层状硫酸铈[C4N2H12]3[Ce2(SO4)6(H2O)2]·H2O的水热合成与晶体结构表征

以哌嗪为模板剂, 在水热条件下合成了一个新的具有二维拓展骨架结构的稀土硫酸盐[C4N2H12]3[Ce2(SO4)6(H2O)2]·H2O, 并对其进行了结构表征和热分析. 单晶结构解析结果表明, 该化合物晶体属于单斜晶系, P21/c空间群, 晶体学参数a=0.66335(10) nm, b=2.8088(4) nm, c=1.02212(15) nm, β=96.160(2)°, V=1.8935(5) nm3, R1=0.0466, wR2=0.1226. 该化合物由[—Ce—S3—Ce—S1—Ce— S3—Ce—S1—]八元环连接形成二维层状结构, 无机层间通过氢键连接成三维无限结构.     

SYNTHESIS AND STRUCTURE OF THE DINUCLEAR MANGANESE-SULFUR COMPLEX (Ph_4As)_2Mn_2(SC_3H_6S)_4

<正> (Ph4As)2[Mn2(SC3H8S)4] was obtained from the reaction of MnCl2-4H2O,Na2(1,2-pdt)(1,2-H2pdt=CH3CH(SH)CH2SH),and Ph4AsCl.C80H64As2Mn2S8, Mr =1301.41,orthorhombic,Pbca; a=10.854(2), b =22.562(6), c =24.545(6)A; V=6010.8A3;Z =4,Dc=1.44g/cm3. The centrosymmetic anion of title compound is a dimer of (Mn(pdt)2]- bridged by one sulfur atom each of the two bridging pdt2-, The atom Mo(Ⅲ) is in a distorted trigonal bipyramidal geometry.     

SYNTHESIS AND STRUCTURE OF (Ph_4P)_2[Ni_3(μ-SC_3H_6S)_4]·2CH_3CN

<正> (Ph4P)2[Ni3(u-SC3H6S)4].2CH3CN was obtained from the reaction of NiCl2.6H2O,Na2(1,2-pdt)(pdtH2=CH3CH(SH)CH2SH) and Ph4PBr.Mr=1361. 80, P21/c,a=10.802(2),b=30.111 (7),c=9. 907(3) A ,B=93. 60(3) ;V= 3216. 0 A3;Z=2,Dc=1. 41g/cm3. The three Ni atoms of the anion are linearly arranged and bridged by four sulfur atoms from the four 1 ,2-propyldithiolato ligands.     

MOLECULAR AND CRYSTAL STRUCTURE OF (μ-HOCH_2 CH_2 S)_2 Fe_2 (CO)_4(PPh_3)_2

<正> The molecular and crystal structure of the complex (μ-HOCH2CH2-S)2 Fe2(CO)4(PPh3)2 synthesized by reaction of ethylene epoxide with (μ-Lis)2Fe2(CO)6, followed by EtOH alcoholysis and PPh3 substitution,was determined by X-ray diffraction technique. The crystals are triclinic,space group P 1,with a= 10. 902(2),b=12. 106 (2),c=16. 123(4) A ,V= 2079. 36A3,α=78. 13(1),β=89. 37(2),γ=87. 93(1)°, Z = 2,Dx=1. 44 g/cm3.μ(MoKa) = 9. 149cm-1, F(000) = 940. The final R and Rw equal to 0. 055 and 0. 068,respectively,for 3598 observed independent reflections. In this molecule two PPh3 ligands are trans to the Fe - Fe bond and axially coordinated to two iron atoms. In addition,two hydroxylethyl groups are attached to bridging sulfur atoms by e-type of bond and thus this molecule is an ee conformer.     

Synthesis, Crystal Structure and Luminescent Property of a Novel 1-D Cadmium(II) Complex: [Cd_2(C_8H_3NO_6)_2(H_2O)_4]_n·2nH_2O

A novel one-dimensional chain-like coordination polymer constructed from 3-nitro- benzene-1,2-dicarboxylic acid, [Cd2(C8H3NO6)2(H2O)4]n·2nH2O, has been synthesized and its structure was determined by X-ray crystallography method. The crystal belongs to monoclinic, space group P21/c with a = 6.1252(8), b = 20.706(3), c = 8.8067(11) , β = 95.608(2)°, V = 1111.6(2) 3, Mr = 751.12, Dc = 2.244 g/cm3, F(000) = 736, μ = 2.011 mm-1, Z = 2, the final R = 0.0262 and wR = 0.0692 for 2338 observed reflections with I > 2σ(I). The structure of the title compound presents a 1-D chain-like structure constructed by dimer units, [Cd2(C8H3NO6)2(H2O)4]n, through two carboxylate oxygen atoms. The fluorescence of the title compound has been also discussed in this paper.     

Synthesis and Structureof［（C_2H_5）_4N］［Mo_3（μ_3－O）（μ－Cl）_3（μ－CH_3CH_2COO）_3Cl_3］

ＳｙｎｔｈｅｓｉｓａｎｄＳｔｒｕｃｔｕｒｅｏｆ［（Ｃ_２Ｈ_５）_４Ｎ］［Ｍｏ_３（μ_３－Ｏ）（μ－Ｃｌ）_３（μ－ＣＨ_３ＣＨ_２ＣＯＯ）_３Ｃｌ_３］ＺｈｕａｎｇＨｏｎｇ－Ｈｕｉ；ＷｕＤｉｎｇ－Ｍｉｎｇ；ＨｕａｎｇＪｉａｎ－Ｑｕａｎ；ＨｕａｎｇＪｉｎ－Ｌ...     

Syntheses and Crystal Structures of Sm(OAr)+2(THF)+3·THF and Sm(OAr)_2(DME)_2 (Ar =C_6H_2-tert-Bu_3-2,4,6)

1 INTRODUCTION The chemistry of divalent lanthanocenes has de- veloped rapidly. Attempts to extend the chemistry beyond the traditional realm of the lanthanocenes have led to the syntheses and structural characteri- zations of a number of lanthanide (II) complexes bearing various ligand systems. Aryloxide ligands have been attractive for their strong bonds with lan- thanide atoms and readily steric modification by the choice of substituents. A series of divalent lantha- nide aryloxides …     

Syntheses and Characterizations of （CH3CH2CH2CH2NH3）6（BiI6）（I）2I3 and （NH3CH2CH2NH3）2Bi2I10

The title compounds have been respectively synthesized by solution process and solvothermal reaction, and their crystal structures were determined by X-ray diffraction method. For （CH3CH2CH2CH2NH3）6（BiI6）（I）2I3 1, it crystallizes in tficlinic, space group P1^- with Mr = 2049.76, a = 8.5719（1）, b = 11.7461（3）, c = 15.700（1）A, V = 1451.4（1）A^3, Z = 1, Dc = 2.345 g/cm^3, F（000） = 924, μ（MoKα） = 8.907 mm^-1, T = 293（2） K, the final R = 0.0655 and wR = 0.0804 for 2399 observed reflections with I 〉 2σ（I）. For （NH3CH2CH2NH3）2Bi2I10 2, it crystallizes in monoclinic, space group P21/n with Mr= 1811.20, a = 8.434（4）, b = 13.862（6）, c = 13.362（6）A, V = 1499.9（12）A^3, Z = 2, Dc = 4.010 g/cm^3, F（000） = 1536,μ（MoKα） = 22.007 mm^-1, T = 293（2） K, the final R = 0.0584 and wR = 0.1451 for 1798 observed reflections with I 〉 2σ（I）. The structures of 1 and 2 contain halobismuthate monomer and dimers, respectively. It is noteworthy that the dimers and their organic counters in 2 connect each other by N…I hydrogen bonds to form a layered structure, and the electrostatic interactions and crystal packing forces between layers give rise to the packing of the crystal. The optical absorption spectra of 1 and 2 reveal the appearance of sharp optical gaps of 2.13 and 2.01 eV, respectively.     

Synthesis and Crystal Structure of {(PPh_3)_2CIRuCIRu(PPh_3) B_(10)H_8[OCH(CH_3)_2)]_2}

1INTRODUCTIONAlthoughseveralhundredpolyhedralmetallaboraneshavebeencharacterized,theincidenceofruthenaboranesisparticularlysurprising.(hThefirstpolyhedralruthenaboraneisstructurallytypifiedbythecompound[(PPh,)2RuB,,HS(OEt),j,whichisobtainedin40%yieldsfromthereactionbetweentRuCI,(PPh,),jandcloso-tB,,H,,j'--inCHCI,/EtOH.tZiWithCH,COOH/THFt'iandC,H,COOH/CH,CI,">insteadofCHCI,/EtOH,twocompoundsF{(PPh,)2Ru}~(p-MeCO,)3--(pH)z-{RuB,,H,}jand[(PPh,)2(PhCOO)RuB,,HSCljhav…     

CRYSTAL STRUCTURE OF TRINUCLEAR MOLYBDENUM CLUS-TER Mo_3(μ_3-S)(μ_2-S_2)_3(Et_2dtc)_3I SYNTHESIZED BY SOLID STATE REACTION

<正> The title cluster compound was synthesized by solid state reaction at low heating temperature. C15H30IMo3N3S13, Mr=1083. 93, monoclinic, P21/n, a = 14.396(3), b = 13. 116(3), c=18. 142(8)A;β= 91. 36(3)°; V =3425(2)A3, Z = 4. Dc = 2. 10g/cm3, F(000) = 2112,μ(MoKa) = 27. 29cm-1, final R = 0. 034, Rw = 0. 051 for 1845 unique observed reflections (I≥3σ(I)). The three Mo atoms form an equilateral triangle with an average side length of 2. 714 A. Each Mo atom is coordinated with seven S atoms forming a distorted pentagonal bipyramid. The iodine atom connects with three S atoms (out of the CMo3] plane) with an average distance of 3. 205 A.The title compound has similar cubane-like cluster core [Mo3S7I] as the compound Mo3(μ3-S)(μ2-S2)3(dtp)3I(dtp= (EtO)2PS2).     

Crystal Structure of {(PPh_3)_2RuB_(10)H_8[(CH_3)_2CHO]_2}

1INTRODUCTIONFromreactionsof[RuCl,(PPh,),jwithcloso-[B,,H,,j'-respectivelyinEtOH/CH,Cl,t'i,CH,COOH/THF"'andC,H,COOH/CH,Cl,">solution,itcanbefoundthatbothalcoholandorganicacidcanreplacehydrogenatomsinborane.Further-more,accordingtotheirdifferentreactiontime(3h,1OOhand113hrespectively),wecanknowthatalcoholismoreactivetoreplacehydrogenatomsinborane.NowinordertoconfirmthisrulefurtherweusePhCH(OH)COOH/(CH3)2CHOHsolutioninsteadofabove-mentionedsolutions.Newcompounds(I)and(II…