镧系与二甘醇-二-(邻羟基苯基)醚配合物的合成与表征

本文合成14种镧系高氯酸盐及硝酸盐分别与二甘醇-二-(邻羟基苯基)醚(记为EO_2(HOP)_2,EO=ethylene oxide,HOP为邻羟基苯基)形成的新配合物,确证组成为Ln(ClO_4)_3·EO_2(HOP)_2·nH_2O(Ln:La-Eu,n=10,Ln:Gd,Dy-Tm,Y,n=7),La_3(NO_3)_9·(EO_2(HOP)_2)_2·3H_2O及La(ClO_4)_2·EO_2H(OP)_25H_2O。文中研究了配合物红外,紫外、~1HNMR谱及~(13)C纵向弛豫时间T_1等,并讨论了共存阴离子、溶剂及配体不同端基对成配的影响。     

稀土与不同端基直链聚醚配合物的合成及其NMR研究

合成了稀土高氯酸盐分别与一缩二乙二醇二甲醚(EO_2Me_2)和一缩二乙二醇-二-(邻甲氧基苯基)醚[EO_2(MeOP)_2]形成的两系列17种新的配合物,经元素分析、IR、NMR表征,确定配合物组成为Ln_3(ClO_4)_9(EO_2Me_2)_5·18H_2O(Ln=La,Pr,Nd)和Ln(ClO_4)_3EO_2Me_2·8H_2O(Ln=Sm,Eu,Gd,Tb,Dy,Ho,Er,Yb,Y)及Ln(ClO_4)_3EO_2(MeOP)_2·6H_2O(Ln=La,Pr,Nd,Eu,Gd).讨论了它们的NMR及光谱等性质,研究了不同端基直链聚醚对配位作用的影响。     

三氯醋酸稀土与1,10—邻菲绕啉配合物的合成与性质研究

关于稀土与1,10-邻菲绕啉(phen)等杂环胺双齿配合物的研究,人们发现当阴离子为Cl~-、NO_3~-时,稀土与杂环胺的配合比为1:2;当阴离子为ClO_4~-时,配比为1:3,1:4;而当阴离子为醋酸根或卤代醋酸根时,配比均为1:1。文献曾报道了在萃取溶液中存在Ln(TCA)_3(phen)_2配合物。本文合成并表征了Ln(TCA)_3(phen)_2·nH_2O(n=0,Ln=La、Nd;n=2,Ln=Gd、Er)的固态配合物,说明以三氯醋酸根(TCA~-)为阴离子时,同样存在Ln:phen=1:2的固态配合物。     

稀土十二氢十二硼酸盐的甲撑双二苯基氧化膦配合物的研究

报告了稀土十二氢十二硼酸盐的甲撑双二苯基氧化膦配合物的合成、波谱(IR、Raman和~(31)PNMR)和热稳定性。配合物的分子式为:(Ln(mppo)_n]_2(B_(12)H_(12))_3式中mppo为甲撑双二苯基氧化膦,Ln=La,n=4;Ln=Pr、Nd、Sm、n=3.5;Ln=Eu、Gd、Tb、Dy、Ho、Er、Tm、Yb、Lu,n=3。     

三元体系Ln(ClO4)3-4-ClCH2COAp-H2O(30℃)的相平衡研究(Ln=La,Sm,Er)

我们测定了三元体系 Ln(ClO_4)_3—4-ClCH_2COA_p—H_2O(Ln=La,Sm,Er)存30℃时的溶度及饱和溶液的折光指数,绘制了相应的溶度图和饱和溶液的折光指数曲线图.体系的溶度曲线和折光指数曲线均由四支组成,分别与4-ClCH_2COA_p、Ln(4-ClCH_2COAp)_3(ClO_4)_3·nH_2O(Ln=La,n=7;Sm,8;Er,4)、Ln(4-ClCH_2COAp)_2(ClO_4)_3·nH_2O(Ln=La,n=7;Sm,6;Er,4)和 Ln(ClO_4)_3·nH_2O(Ln=La,n=8;Sm,9;Er,6)相对应,两类配合物均为固液异组成化合物.     

希土与芳香胺及其氮氧化物形成配合物的研究 X.镧系元素高氯酸盐与2,2''''—二喹啉甲烷固态配合物的合成及性质

本文报道了除钜以外的镧系元素高氯酸盐与2,2′-二喹啉甲烷(Biqm)所形成的新型固体配合物Ln(Biqm)_2(ClO_4)_3·nH_2O(n=0～4)的合成方法,以及通过元素分析、红外光谱、紫外光谱、差热-热重分析、X射线物相分析和电导测定等手段,对配合物的组成和性质所进行的研究结果,推测该类配合物的结构式为:[Ln(Biqm)_2ClO_4]·(ClO_4)_2·nH_2O。     

氮、硫杂冠醚稀土配合物的合成、表征和结构研究

合成和表征了3个杂冠醚配体(L1:单氮杂15C5,L_Ⅱ:单氮杂18C6,L_Ⅲ:1,7—二硫杂18C6)与稀土硝酸盐的配合物:〔Ln(NO_3)_3L_Ⅰ〕(Ln=La～Pr),[Ln-(NO_3)-3L_ Ⅱ〕(Ln=La～Pr),〔HL_Ⅱ〕~+〔Ln(NO_3)_4(OH_2)_2〕~-(Ln=Nd,Sm～Er,Yb),〔Ln(NO_3)_3.L_Ⅲ’(H_2O)](Ln=La～Nd,Sm～Er,Yb),其中L_Ⅲ’表示L_Ⅲ冠醚环上的2个硫原子在与稀土硝酸盐反应的过程中被氧化为亚砜.配合物〔HL_Ⅱ〕~+[Nd(NO_3)_4-(OH_2)_2]的晶体属单斜晶系,空间群P2_1/n,a=1.644 0(5),b=1.739 2(3),c=1.867 5(4)nm,β=107.26(2)°.Z=8,Nd~(+3)与4个二齿NO_3~-和2个水分子配位,形成长链状夹心式结构;配合物〔Er(NO_3)_3L_Ⅲ’(H_2O)〕·CH_3COCH_3的晶体为P2_1/n空间群,a=0.877 2(2),b=1.817 9(7),c=1.854 0(5)nm,β=103.50(3)°,Z=4,Er~(3+)与3个二齿NO_3~-、1个水分子及2个亚砜氧原子形成配位数为9的配合物.     

希土冠醚类配合物的研究--Ⅹ.轻希土硝酸盐与二苯并-24-冠-8固态配合物的合成及性质

在乙腈介质中制得了2:1型固态配合物[Ln(NO_3)_3]_2·DB24C8.2H_2O(Ln=La、Pr)和3:2型固态配合物[Ln(NO_3)_3]_3(DB24C8)_2·3H_2O(Ln=Nd,Sm,Eu)。研究了冠醚及其配合物的红外光谱、紫外光谱、热稳定性及X—射线粉末衍射等性质,观察了它们在常见有机溶剂中的溶解情况,在乙腈中的电导测定结果表明这些配合物均为非电解质。     

希土离子-pmap-吡啶氧化物混配配合物的制备及性质研究

合成了Ce(pmap)_4·2H_2O(pmap=1苯基-3 甲基-4-乙酰基-吡唑酮-5);Ln(pmap)_3·2H_2O·xC_2H_5OH(Ln=La-Nd,x=1;Ln=Sm,Eu-Lu,x=0)以及Ln(pmap)_3·L·H_2O(Ln=La-Lu;L=pyno, 3picno,4picno)等固体配合物,并对它们进行了热谱、电导、红外和可见——紫外光谱等的测试工作。观察到镧系收缩;吡啶氧化物上甲基的取代位置对混配配合物热稳定性的影响;Pr~(3 ),Nd~(3 ),Ho~(3 ),Er~(3 )离子配合物在可见区有超灵敏跃迁现象;从XPS光谱知不同希土离子结合能的对数值与原子序数间有直线关系。     

希土二氯醋酸盐与邻菲罗啉(phen)混配配合物合成和表征

本文采用一种新的合成方法在水、乙醇和四氢呋喃混合溶剂中合成了6种希土二氯醋酸盐与邻菲罗啉(phen)混配配合物,通过元素分析、红外光谱、差热-热重和紫外光谱等分析测试手段研究了配合物的性质,并确定配合物的组成为:Ln(CCl_2HCOO)_3(phen)_2·2H_2O[Ln=Gd、Tb、Er、Yb]和Ln(CCl_2HCOO)_3(phen)_2·H_2O·C_2H_5OH[Ln=Pr、Nd].     

Isoprene polymerization with indolide‐imine supported rare‐earth metal alkyl and amidinate complexes

Reaction of 7‐{(N‐2,6‐R)iminomethyl)}indole ( HL¹ , R = dimethylphenyl; HL² , R = diisopropylphenyl) and rare‐earth metal tris(alkyl)s, Ln(CH₂SiMe₃)₃(THF)₂, generated new rare‐earth metal bis(alkyl) complexes LLn(CH₂SiMe₃)₂(THF) [L = L¹: Ln = Lu ( 1a ), Sc ( 1b ); L = L²: Ln = Lu ( 3a ), Sc ( 3b )] and mono(alkyl) complexes L²₂Lu(CH₂SiMe₃) ( 4a ). Treatment of alkyl complexes 1a and 4a with N,N′‐diisopropylcarbodiimide afforded the corresponding amidinates L¹Lu{iPr₂NC(CH₂SiMe₃)NiPr₂}₂ ( 2a ) and L²₂Lu{iPr₂NC(CH₂SiMe₃)NiPr₂} ( 5a ), respectively. These new rare‐earth metal alkyls and amidinates except 4a in combination with aluminum alkyls and borate generated efficient homogeneous catalysts for the polymerization of isoprene, providing high cis‐1,4 selectivity and high molar mass polyisoprene with narrow molar mass distribution (M_n = 2.65 × 10⁵, M_w/M_n = 1.07, cis‐1,4 98.2%, −60 °C). The environmental hindrance around central metals arising from the bulkiness of the ligands, the Lewis‐acidity of rare‐earth metal ions, the types of aluminum tris(alkyl)s and borate, and polymerization temperature influenced significantly on both the catalytic activity and the regioselectivity. © 2008 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 46: 5251–5262, 2008     

Alternating copolymerization of cyclohexene oxide and carbon dioxide catalyzed by noncyclopentadienyl rare‐earth metal bis(alkyl) complexes

The syntheses of several dialkyl complexes based on rare‐earth metal were described. Three β‐diimine compounds with varying N‐aryl substituents (HL¹=(2‐CH₃O(C₆H₄))N?C(CH₃)CH?C(CH₃)NH(2‐CH₃O(C₆H₄)), HL² = (2,4,6‐(CH₃)₃ (C₆H₂))N?C(CH₃)CH?C(CH₃)NH(2,4,6‐(CH₃)₃(C₆H₂)), HL³ = PhN?C(CH₃)CH(CH₃) NHPh) were treated with Ln(CH₂SiMe₃)₃(THF)₂ to give dialkyl complexes L¹Ln (CH₂SiMe₃)₂ (Ln = Y ( 1a ), Lu ( 1b ), Sc ( 1c )), L²Ln(CH₂SiMe₃)₂(THF) (Ln = Y ( 2a ), Lu ( 2b )), and L³Lu(CH₂SiMe₃)₂(THF) (3). All these complexes were applied to the copolymerization of cyclohexene oxide (CHO) and carbon dioxide as single‐component catalysts. Systematic investigation revealed that the central metal with larger radii and less steric bulkiness were beneficial for the copolymerization of CHO and CO₂. Thus, methoxy‐modified β‐diiminato yttrium bis(alkyl) complex 1a , L¹Y(CH₂SiMe₃)₂, was identified as the optimal catalyst, which converted CHO and CO₂ to polycarbonate with a TOF of 47.4 h^?1 in 1,4‐dioxane under a 15 bar of CO₂ atmosphere (T_p=130 °C), representing the highest catalytic activity achieved by rare‐earth metal catalyst. The resultant copolymer contained high carbonate linkages (>99%) with molar mass up to 1.9 × 10⁴ as well as narrow molar mass distribution (M_w/M_n = 1.7). © 2008 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 46: 6810–6818, 2008     

Thermal and spectral studies of rare earth element 3-methoxy-4-methylbenzonates

3-Methoxy-4-methylbenzoates of Y(III) and lanthanide(III) (La-Lu) were prepared as crystalline compounds with molar ratio of metal to organic ligand of 1.0:3.0 and general formula Ln(C₉H₉O₃)3·nH₂O, where n=2 for Y, La-Er and n=0 for Tm-Lu. IR spectra of the prepared complexes suggest that carboxylate groups are bidentate chelating. During heating dihydrated complexes lose crystallization water molecules in one (Y, La, Pr-Er) or two steps (Ce) and then all the anhydrous complexes decompose directly to oxides Ln₂O₃, CeO₂, Pr₆O₁₁ and Tb₄O₇.Vadim Mamleev is grateful to Region Nord-pas-de-Calais (France) for financial support and to laboratory PERF of ENSCL for its kind invitation to continue the joint work on thermal analysis.     

Chiral Benzamidinate Ligands in Rare‐Earth‐Metal Coordination Chemistry

The treatment of the recently reported potassium salt (S)‐N,N′‐bis‐(1‐phenylethyl)benzamidinate ((S)‐KPEBA) and its racemic isomer (rac‐KPEBA) with anhydrous lanthanide trichlorides (Ln=Sm, Er, Yb, Lu) afforded mostly chiral complexes. The tris(amidinate) complex [{(S)‐PEBA}₃Sm], bis(amidinate) complexes [{Ln(PEBA)₂(μ‐Cl)}₂] (Ln=Sm, Er, Yb, Lu), and mono(amidinate) compounds [Ln(PEBA)(Cl)₂(thf)_n] (Ln=Sm, Yb, Lu) were isolated and structurally characterized. As a result of steric effects, the homoleptic 3:1 complexes of the smaller lanthanide atoms Yb and Lu were not accessible. Furthermore, chiral bis(amidinate)–amido complexes [{(S)‐PEBA}₂Ln{N(SiMe₃)₂}] (Ln=Y, Lu) were synthesized by an amine‐elimination reaction and salt metathesis. All of these chiral bis‐ and tris(amidinate) complexes had additional axial chirality and they all crystallized as diastereomerically pure compounds. By using rac‐PEBA as a ligand, an achiral meso arrangement of the ligands was observed. The catalytic activities and enantioselectivities of [{(S)‐PEBA}₂Ln{N(SiMe₃)₂}] (Ln=Y, Lu) were investigated in hydroamination/cyclization reactions. A clear dependence of the rate of reaction and enantioselectivity on the ionic radius was observed, which showed higher reaction rates but poorer enantioselectivities for the yttrium compound.     

4-Chloro-2-methoxybenzoates of heavy lanthanides(III) and yttrium(III)

4-Chloro-2-methoxybenzoates of heavy lanthanides(III) and yttrium(III) were obtained as mono-, di-, tri-or tetrahydrates with metal to ligand ratio of 1:3 and general formula Ln(C₈H₆ClO₃)₃·nH₂O, where n=1 for Ln=Er, n=2 for Ln=Tb, Dy, Tm, Y, n=3 for Ln=Ho and n=4 for Yb and Lu. The complexes were characterized by elemental analysis, FTIR spectra, TG, DTA and DSC curves, X-ray diffraction and magnetic measurements. The carboxylate group appears to be a symmetrical bidentate chelating ligand. All complexes are polycrystalline compounds. The values of enthalpy, ΔH, of the dehydration process for analysed complexes were also determined. The solubilities of heavy lanthanide(III) 4-chloro-2-methoxybenzoates in water at 293 K are of the order of 10⁻⁴ mol dm⁻³. The magnetic moments were determined over the range of 76–303 K. The results indicate that there is no influence of the ligand field of 4f electrons on lanthanide ions and the metal ligand bonding is mainly electrostatic in nature.     

希土硼氢化物的研究 Ⅹ.含[B10H9NH2COCH=CH2]-的双苯甲酰丙酮缩1,3-丙二胺希土(Ⅲ)配合物的研究

将闭式+氢+硼酸阴离子酰胺衍生物[B₁₀H₉NH₂COCH=CH₂]^-、双苯甲酰丙酮缩1,3-丙二胺C₆H₅C(OH)=CHC(CH₃)=N(CH₃)CH=C(OH)C₆H₅(Bapn)及希土氯化物在丙酮-乙醇混合溶剂中进行反应,得到分子式为Ln(Bapn)₃[B₁₀H₉NH₂COCH=CH₂]₃(Ln=La,Nd,Sm,Eu,Gd,Dy)的混式配体希土配合物。通过元素分析、IR、¹H NMR及摩尔电导率的测定对配合物进行了表征,还通过DTA-TG方法研究了它们的热性质。     

希土高氯酸盐与N,N''—二(2—吡啶亚甲基)—1,2—乙二胺配合物的合成及性质研究

自六十年代以来,希土离子与芳香胺及其衍生物的配合物研究受到人们的普遍重视。     

希土元素异硫氰酸盐与苄胺配合物的制备、性质及标准生成焓的测定

制备了Pr、Yb两种希土元素异硫氰酸盐与苄胺的固体配合物.并对其进行了组成分析、红外光谱分析、X射线衍射物相分析和热重分析.测量了298.15K时两种固体配合物RE(NCS)₃·4C₆H₅CH₂NH₂在HCl水溶液中的反应热和相应的两种希土元素异硫氰酸盐水合物RE(NCS)₃·n₁H₂O(RE为Pr时,n₁=7;RE为Yb时,n₁=6)在C₆H₅CH₂NH₂-HCl^-H₂O溶液中的积分溶解热以及苄胺C₆H₅CH₂NH₂在HCl水溶液中的反应热.藉助本文所设计的热化学循环,求得了这两种配合物的标准生成焓,还计算了它们的晶格能.     

硼合扁桃酸、含氮配体希土配合物的研究

本文合成了镧，铈，镨的硼合扁桃酸配合物，并进一步用硼合扁桃酸镧同喹啉，邻菲罗啉，联吡淀等含氮配体作用制备出了三元配合物。用化学分析，红外光谱，氢核磁共振谱，紫外一可见光谱，摩尔电导及热谱等物理化学测试手段，确定了这些化合物的组成和成键情况，并对其某些物理化学性质进行了研究。     

希土配合物的研究——Ⅷ.1, 4-双(1''-苯基-3''-甲基-5''-氧代吡唑酮基-4'')代-1, 4-丁二酮(BPMPBD)与希土元素配合物的合成及表征

在乙醇-水溶液中,当pH=5-6时,用希土硝酸盐与BPMPBD反应,合成了15种希土元素(除Sc、Pm外)的二元配合物.通过化学分析和元素分析确定了配合物的组成为REL₂·nH₂O(RE=La,n=5,RE=Y,n=4,RE=Pr、Nd、Sm、Eu、Gd,n=3),RE₂L₃·5H₂O(RE=Tb、Dy、Ho、Er、Tm、Yb、Lu)及CeL₂·4H₂O.研究了这些配合物的一些性质及红外光谱、紫外光谱、核磁共振、荧光光谱和差热分析,认为重希土配合物具有双核结构.