[C_5H_5Fe(CO)_2]LnCl_2·nTHF和[C_5H_5Fe(CO)_2][C_5H_4(SiMe_3)]LnCl·nTHF双核配合物的合成

合成了稀土铁双核配合物:〔C_5H_5Fe(CO)_2〕LnCl_2·nTHF(Ln=Nd,Sm,Gd;n=1,2)和〔C_5H_5Fe(CO)_2〕〔C_5H_4(SiMe_3)〕·LnCl·nTHF(Ln=Nd,Sm,Gd;n=0,1,2)。元素分析,热分析,红外光谱和质谱分析确认了这两种配合物。红外光谱数据表明铁与稀土原子是以羰基桥连接。晶体结构分析表明〔(C_5H_5Fe(CO)_2〕Na·4THF是〔C_5H_5Fe(CO)_2〕LnCl_2·nTHF合成的中间体。     

苄基环戊二烯基稀土二氯化物的合成和表征

合成了苄基环戊二烯基稀土二氯化物,经元素分析、热分析、红外光谱、质谱及核磁共振谱分析,证实其组成为C_6H_5CH_2C_5H_4LnCl_2·nTHF(C_6H_5CH_2C_5H_4=苄基环戊二烯,Ln=Nd,Sm,Gd,n=1,2)。对新化合物苄基环戊二烯进行了表征,同时还测定了中间物C_6H_5CH_2C_5H_4Na·THF的晶体结构。     

苯基稀土氯化物的合成及其表征

1970年,Hart等首先合成了Sc(C_6H_5)_3、Y(C_6H_5)_3、LiLa(C_6H_5)_4和LiPr(C_6H_5)_4。1972年,Cotton等测定了[Lu(2,6-(CH_3)_2C_6H_3)_4]·[Li·4THF]的晶体结构。1986年,陈文启等人合成了Nd(C_6H_5)_3,Gd(C_6H_5)_3和LiNd(C_6H_5)_4。本文首次合成了苯基稀土氯化物C_6H_5LnCl_2·nTHF(Ln=Pr,Sm,Gd,n=3,4);C_6H_5LnCl_2·LiCl·nTHF(Ln=Pr、Nd、Sm、Gd,n=2、3、5);(C_6H_5)_2GdCl·LiCl·2THF;[(C_6H_5)_2NdCl]_2·LiCl·4THF。测定了C_6H_5GdCl_2·4THF的晶体结构。     

利用歧化反应的逆反应合成C_5H_5LnCl_2·2LiCl·5THF配合物(Ln=La,Nd)

由于镧系收缩和配位不饱和性,导致长期不能合成轻稀土环戊二烯基氯化物。陈文启等借严格控制氯化稀土与环戊二烯基钠的摩尔比为1:0.5,制备了环戊二烯基轻稀土二氯化物(Pr、Ce、Nd),但即使将这一摩尔比调整为1:0.25也不能得到类似的镧的化合物。李毅等以LnCl_3—LiCl(Ln=La、Nd)的四氢呋喃溶液和等摩尔的C_5H_5Na反应,以比较高的收率制备了[Li(THF)_2]_2(μ-Cl)_4C_5Ln·THF,并测定了其晶体结构。我们     

配合物[Li(THF)_2]_2(μ—Cl)_4[(η~5—CH_3C_5H_4)Nd·THF]的合成及其晶体结构

环戊二烯基希土氯化物是一类合成希土有机配合物的重要前身。尽管在1980年前没能成功地合成含轻希土元素的这类配合物,但目前已发现,采用具有较大体积的取代环戊二烯做配体,如C_5Me_5H,C_5H_3〔Si(CH_3)_3〕_2H,C_5Me_4C_3H_7H和桥联的配体(C_5H_4)_2(CH_2)_3H_2都可得到相应的取代环戊二烯基轻希土氯化物。控制LnCl_3和CpNa的反应摩尔比也可以成功地得到这类轻希土的环戊二烯基氯化物。     

金属簇合物η~5-RC_5H_4(CO)_2MCo_3(CO)_6(μ-CO)_3的合成、结构及反应机理的研究

通过金属单键化合物[η~5-RC_5H_4(CO)_3M]_2和CO_2(CO)_8的热反应,制得8个含烷基环戊二烯基配体的金属四面体簇合物η~5-RC_5H_4(CO)_2MCo_3(CO)_6(μ-CO)3(M=Mo,W;R=CH_3,C_2H_5,n-C_4H_9,C_6H_5CH_2)。除用元素分析,IR,~1H NMR和MS表征了它们的结构以及用X光衍射技术测得η~5-n-C_4H_9C_5H_4(CO)_2MoCo_3(CO)_6(μ-CO)_3的单晶分子结构外,尚对该反应的机理进行了研究。所测晶体属空间群P2_1/c,晶胞参数a=10.088 (2),b=13.063 (3),c=18.320 (5) A;β=96.04 (2)°,最终偏差因子R=0.041。     

轻稀土配合物[Li·(DME)_3ⅡCH_3C_5H_4Ln(NPh_2)_3l(Ln=La、Pr、Nd)的合成和镧配合物的晶体结构

CH_3C_5H_4LnCl_2·2LiCl·nTHF与2mol的LiNPh_2在THF、已烷和甲苯混合液中反应,经DME萃取,得到[Li·(DME)_3][(η~5-CH_3C_5H_4)Ln(NPh_2)_3](Ln=La,Pr,Nd)。对其进行了元素分析、IR和NMR表征。镧配合物单晶结构测定表明,属单斜晶系,P2_1/a空间群,晶胞参数为α=1.7461(6)nm,b=1.6576(5)nm,c=1.8335(6)nm,β=96.04°,V=5.277um~3,Z=4,D_c=1.26g/cm_3,R=0.057,R_w=0.048。该配合物是一个离子对,La-N和La-C(环)键的平均距离分别为0.2459(8)和 0.2843(11)nm。稀土离子形成一个六配位的扭曲四面体。     

取代环戊二烯基钕、钆、镱络合物的合成

本文合成了一些[M(THF)_2][L_2LnCl_2]络合物,其中Ln为Nd,Gd或Yb;L为C_5Me_5,C_5Me_4C_2H_5或C_5Me_4C_3H_7;M为Li或K。并分离了中性络合物(C_5Me_4C_3H_7)_2NdCl。这些络合物对空气和水非常敏感,除了含K的阴离子型络合物外,其它络合物都易溶于汽油,苯和甲苯等非极性溶剂。络合物均经元素分析、红外和核磁鉴定。     

2,4—二甲基戊二烯基稀土配合物的合成

通过元素分析、红外光谱、核磁共振谱、热重分析、晶体结构的测定以及对化合物水解产物的分析。确认合成了下列配合物: 〔η~5-2,4-(CH_3)_2C_5H_5〕LnCl_2·3THF(Ln=Nd,Sm,Gd), 〔η~5-2,4-(C_3H)_2C_5H_5〕_2LnCl·THF(Ln=Nd,Sm), 〔η~5-2,4-(CH_3)_2C_5H_5)_3Ln(Ln=La,Sm,Gd), (2,4-(CH_3)_2C_5H_5=2,4-二甲基戊二烯基。 THF=四氢呋喃     

三甲硅基环戊二烯基稀土二氯化物的合成

1978年Lappert等人首先合成了二(三甲硅基环戊二烯基)稀土氯化物[Li(THF)](Me_3SiC_5H_4)_2LnCl] (Ln=Y,Yb)和Yb(C_5H_4SiMe_3)_2。三甲硅基环戊二烯基稀土二氯化物,则未见报导.采用三甲硅基环戊二烯作为合成稀土金属有机化合物的配体,不仅可以增加所合成的稀土化合物在非极性溶剂中的溶解度,而且在反应过程中可以减小歧化反应的发生,得到所要求的产物.我们探索了三甲硅基环戊二烯基稀土二氯化物的合成,并对所得到的产物进行了鉴定.     

Crystal Structure of [PrAl（CF3COO）2（CF3CHOO）（C2H5）2（C4H8O）2]2

[PrAl(CF3COO)2(CF3CHOO)(C2H5)2(C4H8O)2]2 Mr=1420.56, monoclinic, P21/n, a=10.651(6), b=24.276(9), c=11.110(5)(), β=107.650(4)°, V=2737.4(1)()3, Z=2, Dc=3.45 g/cm3, F(000)=2816, T=233K, MoKα radiation (λ=0.71069()), μ(MoKα)=38.017 cm-1, R=0.048 for 2847 observed reflections (I≥3σ(I)). It is isostructural with [LnAl(CF3COO)2(CF3CHOO)-R2(C4H8O)2]2 (Ln=Ho, R=Et; Ln=Nd, Y, R=iBu). Pr3+ is coordinated by eight oxygen atoms from five bridging ligands and two THF forming a distorted bicap-prism.     

双齿配体八配位镧系配合物的结构化学研究——Ⅱ.[C4H9O]+[Ln(S2CNC4H8)4]-(Ln=La和Nd)的合成和结构

镧系配合物[C_4H_9O]~+[Ln(S_2CNC_4H_8)_4]~-是从LnCl_3(Ln=La和Nd)和NH_4(S_2CNC_4H_8)在THF中反应得到的。 [C_4H_9O]~+[Ln(S_2CNC_4H_8)_4)~-的晶体和分子结构通过单晶X-射线结构分析获得,结晶学参数列于下表。 晶体结构是从Patterson和Fourier方法解出,并用全矩阵最小二乘法修正。最后偏离因子对于La配合物,R=0.064,R_w=0.0681;而对于Nd配合物;R=0.051,R_w=0.059。晶体由正离子[C_4H_9O]~+和负离子[Ln(S_2CNC_4H_8)4]~-组成,在负离子中ln原于是由八个硫原子构成扭变的三角形十二面体配位。Ln-S平均距离分别为2.974(La)和2.908(Nd)。     

Organoamido- and aryloxo-lanthanoids. XIII [1]. Organometallic compounds of the lanthanoids. CV [2]. New Lanthanoid(III) Complexes with Pyrazolate Ligands

The complexes Er(Me₂pz)₃(thf) and Ln(Ph₂pz)₃(thf)_n (Ln = Sc, Y, Gd, Er, n = 2; Ln = Lu, n = 3) (Me₂pz^? = 3,5-dimethylpyrazolate, thf = tetrahydrofuran, Ph₂pz^? = 3,5-diphenylpyrazolate) have been prepared by reaction of the lanthanoid metal with bis(pentafluorophenyl)mercury and the pyrazole in thf. The Ln(Ph₂pz)₃(thf)₂ complexes are considered to be eight coordinate with three η²-Ph₂pz ligands. Other lanthanoid pyrazolate complexes, Y(pz)₃(thf)₂, La(Me₂pz)₃(thf), Cp₂Ln(Me₂pz)(thf)_n (Ln = Y, Lu, n = 0; Ln = Lu, n = 1), (C₅Me₅)₂Y(pz)(thf), (C₅Me₅)₂Y(Mepz)(thf), (C₅Me₅)₂Y(Me₂pz)(thf)₂ (pz^? = pyrazolate, Mepz^? = 3-methylpyrazolate, Cp = cyclopentadienyl) have been synthesized by reaction of LnCl₃, Cp₂LnCl, or (C₅Me₅)₂LnCl with the appropriate sodium pyrazolate in thf. The structure of Ln(Me₂pz)₃(thf) (Ln = La or Er) is considered to be a symmetrical dimer with four chelating and two bridging Me₂pz groups, and two bridging thf ligands, whereas the cyclopentadienyl complexes are most likely dimers with bridging pyrazolate groups, and lattice thf of solvation.     

Detailed Analysis of the Crystal Structures and Magnetic Properties of a Dysprosium(III) Phthalocyaninato Sextuple-Decker Complex: Weak f–f Interactions Suppress Magnetic Relaxation

In the research field of single-molecule magnets (SMMs), lanthanoid–lanthanoid interactions, so-called f–f interactions, are known to affect the SMM properties, although their magnitudes are small. In this article, an SMM with very weak f–f interactions is reported, and the effects of the interactions on the SMM properties are discussed. X-ray structural analysis of the Dy^III-Cd^II-phthalocyaninato sextuple-decker complex (Dy₂Cd₃) reveals that the intramolecular Dy−Dy length in Dy₂Cd₃ is more than 13 Å, which is longer than the intermolecular Dy−Dy length. Even though the two Dy^III ions are far apart, intermolecular ferromagnetic dipole–dipole interactions are observed in Dy₂Cd₃. From detailed analysis of ac magnetic susceptibilities, quantum tunneling of the magnetization (QTM) in Dy₂Cd₃ is partially suppressed owing to the existence of very weak Dy−Dy interactions. Our results show that even very weak Dy−Dy interactions act as a dipolar bias, suppressing QTM.     

[Li3DME][(η~5-C_5H_5)_3Nd(μ-H)Nd(η~5-C_5H_5)_3]的合成及其分子结构

标题配合物是以THF作溶剂,通过(C_5H_5)_2NdCl·ZLiCl和甲基萘钠的还原反应合成的。其晶体属单斜晶系,P 2/c空间群,晶胞参数α=9.235(2)A,b=11.695(2)A,c=20.810(3)A,β=92.88(1)°,Z=2。研究结果表明,标题配合物由相互不相联的〔Li3DME〕~ 和〔(η~5-C_5H_5)_3Nd(μ-H)Nd(η~5-C_5H_5)_3〕~-离子对组成。阳离子中,Li原子与由3个DME提供的6个O原子配位,形成八面体构型,Li—O平均键长为2.116A;阴离子中,2个Nd原子不直接键合,系通过桥H联接,Nd—H=2.19A。此外,每个Nd原子各有3个C_5H_5~-与之配位,Nd—C平均键长为2.812A。     

Catalytic activity of some organolanthanoid derivatives in styrene and propene polymerization

Organolanthanoids of several classes were examined as potential styrene and propene polymerization catalysts. They are: molecular hydrides of divalent lanthanoids (samarium, europium, ytterbium); naphthalene and stilbene complexes of neodymium(III), samarium(II), europium(II), ytterbium(II), lutetium(III); amides and alkoxides (including heterobifunctional derivatives) of praseodymium(III), neodymium(III), samarium(II), europium(II), thulium(III), ytterbium(II, III); thiolate of samarium(III); phenyl and phenylethinyl derivatives of europium(II), thulium(III), ytterbium(II); methylytterbium cluster Yb₈ (μ‐CH₃)₁₄(μ‐CH₂)(THF)₆; heterobimetallic samarium(II), ytterbium(II, III) complexes; diazabutadiene ytterbium(III) derivatives; metallic praseodymium and ytterbium, activated by iodine. The highest activity in styrene polymerization revealed hydrides, naphthalene and stilbene complexes of samarium(II), europium(II) and ytterbium(II). In the propene polymerization only [(η⁵‐C₅H₄)CH₂CH­(CH₂OBu)(η¹‐O)]YbMe(THF) displayed noticeable activity.Copyright © 2001 John Wiley & Sons, Ltd.     

Lanthanoid Complexes as Molecular Materials: The Redox Approach

The development of molecular materials with novel functionality offers promise for technological innovation. Switchable molecules that incorporate redox-active components are enticing candidate compounds due to their potential for electronic manipulation. Lanthanoid metals are most prevalent in their trivalent state and usually redox-activity in lanthanoid complexes is restricted to the ligand. The unique electronic and physical properties of lanthanoid ions have been exploited for various applications, including in magnetic and luminescent materials as well as in catalysis. Lanthanoid complexes are also promising for applications reliant on switchability, where the physical properties can be modulated by varying the oxidation state of a coordinated ligand. Lanthanoid-based redox activity is also possible, encompassing both divalent and tetravalent metal oxidation states. Thus, utilization of redox-active lanthanoid metals offers an attractive opportunity to further expand the capabilities of molecular materials. This review surveys both ligand and lanthanoid centered redox-activity in pre-existing molecular systems, including tuning of lanthanoid magnetic and photophysical properties by modulating the redox states of coordinated ligands. Ultimately the combination of redox-activity at both ligands and metal centers in the same molecule can afford novel electronic structures and physical properties, including multiconfigurational electronic states and valence tautomerism. Further targeted exploration of these features is clearly warranted, both to enhance understanding of the underlying fundamental chemistry, and for the generation of a potentially important new class of molecular material.