配合物[M(CO)3(PPh2py)2](M=Fe,Ru)异构体的理论研究

对PPh2py配合物[M(CO)3(PPh2py)2](M=Fe, Ru)的三种构型的异构体1-6进行了研究. 其中PPh2py以两个P原子与M配位形成HH构型1(Fe)和4(Ru), 以一个P和一个N原子与M配位形成HT构型2(Fe)和5(Ru), 以两个N原子与M配位形成HH’构型3(Fe)和6(Ru). 结果表明, (1) PPh2py中P原子对HOMO轨道的贡献最大, PPh2py作为电子给体时易以P原子与金属原子结合. (2)从分子能量和相互作用能数据表明, 配合物中HH构型最稳定, HH'构型最不稳定, 这与合成产物为HH构型的结果一致. (3) 键长和Wiberg键级均表明P—M键比N—M键结合力强. P、M原子间存在σ键, 而N、Fe原子间仅存在nN→n*M或nN→σ*M-P的电荷转移作用. (4) HH构型中M对HOMO的贡献最大, PPh2py向M的电荷转移最强, 使M的负电荷最大, 故HH构型最易作为电子给体以M原子与第二个金属配位形成双核配合物.     

[Ti（CO）6（MPEt3）]^—（M=Au,Ag,Cu）配合物稳定性及共电子性质的量子化学研究

采用ab initioHF和密度泛函B3LYP方法对[Ti(CO)6(MPEt3)]^配合物稳定性进行了系统理论计算，并对Ti-Au金属－金属相互作用能运用完全均衡校正法对基函数重叠误差（BSSE）进行较正。理论优化的结构与X射线衍射晶体结构实验基本相符，Ti-Au相互作用能为10．8575eV(B3LYP/BSSE)。进一步探讨Cu族元素为中心的同系配合物离子[Ti(CO)6(MPEt3)]^-(M=Cu,Ag,R=Me,H)的电子性质及结合能规律，结果表明：Cu族化合物中，Au形成了较为稳定的化合物，表现出金属－金属相互作用影响比较明显。     

C60[RuHCl（CO）（PPh3）]3配合物的合成和表征

富勒烯配合物的制备及其性质的研究是目前富勒烯化学最为活跃的研究领域之一［１］,人们正致力于探索富勒烯各类衍生物的结构与性质之间的依赖关系,以期合成出具有特殊性能的富勒烯配合物,为富勒烯的实际开发应用奠定基础。本文首次合成Ｃ６０［ＲｕＨＣｌ（ＣＯ）（ＰＰｈ３）］３配合物,采用元素分析、红外光谱、电子光谱进行鉴定和表征,并推测了其结构。１　实验部分１．１　Ｃ６０［ＲｕＨＣｌ（ＣＯ）（ＰＰｈ３）］３的合成合成按下列反应进行：ＲｕＣｌ３＋３ＰＰｈ３＋ＨＣＨＯ→ＲｕＨＣｌ（ＣＯ）（ＰＰｈ３）３ＲｕＨＣｌ（…     

双膦配合物Ru（OAc）2（Ph3P）（dppe）和Ru（OAc）2（dppe）2的设计合成,表…

Ｒｕ（ＯＡｃ）２（Ｐｈ３Ｐ）２和１或２摩尔的双－（二苯基膦）乙烷（ｄｐｐｅ）在回流的甲苯中反应，分别生成双膦配位的Ｒｕ（ＯＡｃ）２（Ｐｈ３Ｐ）（ｄｐｐｅ）和Ｒｕ（ＯＡｃ）２（ｄｐｐｅ）２。并进行了元素分析、ＩＲ、ＮＭＲ等谱学表征。在温度－５０至４０℃的范围内，测定了Ｒｕ（ＯＡｃ）２（Ｐｈ３Ｐ）（ｄｐｐｅ）的＾３１Ｐ｛＾１Ｈ｝ＮＭＲ谱，讨论了配合物中膦配体的配位状态。在反应温度３０至９０℃、氢压１．     

η^2—C60[RhCI（CO）（PPh3）2]配合物的合成与表征

从1985年Smalley等^[1]发现C60等富勒烯至1996年富勒烯的发现者获诺贝尔化学奖期间,在化学、材料、物理等领域形成了富勒烯的研究热潮^[2-5]。现在科学工作者正以较大的注意力投向富勒烯的化学修饰,研究富勒烯各类衍生物的结构与性能之间内在联系规律,以期望在开发应用方面取得突破性进展,为此也十分重视对具有特殊组成与结构的富勒烯衍生物的研究。本文首次合成出η^2-C60[RhCI(CO)(PPh3)2]配合物,并对其结构进行了表征。     

含有双齿配体二苯基膦基吡啶（Ph2PPy）的羧基镍配合物——（Ph2PPy）2Ni（CO）2

应用一个简单新方法，在锌粉存在和常温常压下，（Ph2PPy)2NiCl2与CO得到新配合物（Ph2PPy)2Ni(CO)2。对后者经X衍射测定了晶体及分子结构。该晶体属正交晶系Pcab。晶胞参数为：α=12.044（3）°/A，b=21.322(5)°/A,c=24.925(5)°/A,Z=8.R=0.051和Rw＝0.055。该分子中的镍原子配位为四面体构型。     

Syntheses, Structural Characterization of Fe and Ni Complexes with Polypyrazolyl Borate Ligand ： Fe [ HB （pz） 3 ] 2 and Ni [ HB （pz） 3 ] 2

Fe(Ⅱ) complex Fe[HB(pz)3]2(compound 1, pz=pyrazole) and Ni(Ⅱ) complex Ni[HB(pz)3]2(compound 2) have been obtained by the reaction of MCI2(M=Fe and Ni) with NaHB(pz)3 in MeOH. The two complexes(compounds 1 and 2) were characterized by IR, NMR, elemental analysis and X-ray diffraction. Compound 1 crystallizes in space group P21/c with a=1.224(3) nm, b=1.161(2) nm, c=1.648(3) nm, β=107.62(15)°, V=2.233(8) nm3, Z=2. Compound 2 crystallizes in space group P21/c with a=0.97926(18) nm, b=1.7423(3) nm, c=1.3156(2) nm, β=97.055(16)°, V=2.2277(7) nm3, Z=4. The results of X-ray structural analyses show that both compounds 1 and 2 are monomeric neutral, possessing a similar coordination mode and a similar structure around the metal centers. The related spectral characterizations, steric effects and binding properties are discussed.     

A Convenient Synthesis and Properties of Ru（bpy）2[bpy（CO2H）-（CO2Et）]（PF6）2 Photosensitive Dye

A novel Ru(Ⅱ) tris-bipyridyl complex, Ru(bpy)2[bpy(CO2H)(CO2Et)][PF6]2 is prepared in a simple and convenient process. It will be an alternative of Ru(bpy)2bpy(CO2Et)2(PF6)2 to be used in solar cells as photosensitive dyes.     

双膦钌配合物Ru（OAc）_2（Ph_3P）（dppm）和Ru（OAc）_2（

合成了双膦醋酸钌配合物，不同温度的￣１ＨＮＭＲ谱表明，两个醋酸根分别以单齿和双齿配体与中心钌（Ⅱ）配位；￣（３１）ＰＮＭＲ和Ｘ－射线结构分析表明膦配体为面式构型。配合物对丙烯酸和苯乙烯有选择氢化活性。     

配合物[Fe(CO)3(PPh2R)2(HgCl2)] (R=pym,fur, py,thi)的Fe-Hg相互作用及31P化学位移

In order to study the effects of R group on Fe-Hg interactions and 31P chemical shifts, the structures of mononuclear complexes Fe(CO)3(PPh2R)2 (R=pym: 1, fur: 2, py: 3, thi: 4; pym=pyrimidine, fur=furyl, py=pyridine, thi=thiazole) and binuclear complexes [Fe(CO)3(PPh2R)2(HgCl2)] (R=pym: 5, fur: 6, py: 7, thi: 8) were studied by using the density functional theory (DFT) PBE0 method. The 31P chemical shifts were calculated by PBE0-GIAO method. Nature bond orbital (NBO) analyseswere also performed to explain the nature of the Fe-Hg interactions. The conclusions can be drawn as follows: (1) The complexes with nitrogen donor atoms are more stable than those with O or S atoms. The more N atom there are, the higher is the stabilitity of the complex. (2) The Fe-Hg interactions play a dominant role in the stabilities of the complexes. In 5 or 6, there is a σ-bond between Fe and Hg atoms, However, in 7 and 8, the Fe-Hg interations act as σP-Fe→nHg and σC-Fe→nHg delocalization. (3) Through Fe邛Hg interactions, there is charge transfer from R groups towards the P, Fe, and Hg atoms, which increases the electron density on P nucleus in binuclear complexes. As a result, compared with their mononuclear complexes, the 31P chemical shifts in binuclear complexes show some reduction.     

Fe–Hg Interactions and P Chemical Shifts in [Fe(CO)3 (PPh2R)2(HgCl2)] (R=pym, fur, py, thi)

In order to study the effects of R group on Fe–Hg interactions and 31P chemical shifts, the structures of mononuclear complexes Fe(CO)₃(PPh₂R)₂ (R=pym:1, fur: 2, py: 3,thi: 4; pym=pyrimidine, fur=furyl, py=pyridine, thi=thiazole) and binuclear complexes [Fe(CO)₃(PPh₂R)₂(HgCl₂)] (R=pym: 5, fur: 6, py: 7, thi: 8) were studied using the density functional theory (DFT) PBE0 method. The 31P chemical shifts were calculated by PBE0-GIAO method. Nature bond orbital (NBO) analyses were also performed to explain the nature of the Fe–Hg interactions. The conclusions can be drawn as follows: (1) The complexes with nitrogen donor atoms are more stable than those with O or S atoms. The more N atoms there are, the higher is the stabilility of the complex. (2) The Fe–Hg interactions play a dominant role in the stabilities of the complexes. In 5 or 6, thereisa σ-bond between Fe and Hg atoms. However, in 7 and 8, the Fe–Hg interactions act as σ_P–Fe→n_Hg and σ_C–Fe→n_Hg delocalization. (3) Through Fe→Hg interactions, there is charge transfer from R groups towards the P, Fe, and Hg atoms, which increases the electron density on P nucleus in binuclear complexes. As a result, compared with their mononuclear complexes, the 31P chemical shifts in binuclear complexes show some reduction.     

Ir(CO)Cla(Ph2Ppy)2HgClb(HgCl2)c(a,b=1,2;c=0,1)的Ir-Hg相互作用和氧化还原反应性质

应用密度泛函理论(DFT)的PBEO方法,金属原子采用SDD基组,H、C、O和N原子采用6-31G*基组,P和Cl原子采用6-311G*基组,对单核配合物Ir(CO)Cl(Ph2Ppy)2(1),双核配合物Ir(CO)(Cl)2(Ph2Ppy)2HgCl(2)、Ir(CO)Cl(Ph2Ppy)2HgCl2(3)和Ir(CO)(Cl)2(HgCl2)(Ph2Ppy)2HgCl(4)进行结构优化,并在优化的基础上采用基组重叠误差(BSSE)校正计算相互作用能,通过自然键轨道(NBO)和前线轨道分析研究Ir-Hg相互作用和氧化还原反应的实质.通过计算发现,Ir(CO)Cl(Ph2Ppy)2与HgCl2发生氧化还原反应得到的产物2和4比非氧化还原产物3稳定.Ir-Hg相互作用强度顺序为3＜4＜2,且随着Ir-Hg相互作用强度增大,HOMO轨道中Ir和Hg成分逐渐趋于接近.配合物2和4都具有一对Ir-Hg成键与反键轨道,其成键轨道的组成分别为0.5985sd0.06Hg+0.8012sd2.48Ir和0.5794sd0.05Hg+0.8151sd2.48Ir,但3中Ir与Hg的相瓦作用较弱,只存在弱相互作用(电荷转移作用),表现为nIr→nHg的直接作用和σIr-P(1)→nHg、σIr-C(1)→nHg的间接作用.     

Low oxidation state ruthenium chemistry : IV. The reactions of M(CO)2(PPh3)3 complexes (M = Fe,Ru) and the hydrogenation and isomerization of alkenes catalyzed by RuL(CO)2(PPh3)2 (L = H2, PPh3)

The complexes M(CO)₂(PPh₃)₃ (I, M = Fe; II, M = Ru) readily react with H₂ at room temperature and atmospheric pressure to give cis-M(H)₂(CO)₂(PPh₃)₂ (III, M = Fe;IV,M = Ru). I reacts with O₂ to give an unstable compound in solution, in a type of reaction known to occur with II which leads to cis-Ru(O₂)(CO)₂(PPh₃)₂(V). Even compound IV reacts with O₂ to give V with displacement of H₂; this reaction has been shown to be reversible and this is the first case where the displacement of H₂ by O₂ and that of O₂ by H₂ at a metal center has been observed. III and IV are reduced to M(CO)₃(PPh₃)₂ by CO with displacement of H₂; Ru(CO)₃- (PPh₃)₂ is also formed by treatment of IV with CO₂, but under higher pressure. Compounds II and IV react with CH₂CHCN to give Ru(CH₂CHCN)(CO)₂- (PPh₃)₂(VI) which reacts with H₂ to reform the hydride IV.cis-Ru(H)₂(CO)₂(PPh₃)₂(IV) has been studied as catalyst in the hydrogenation and isomerization of a series of monoenes and dienes. The catalysts are poisoned by the presence of free triphenylphosphine. On the other hand the ready exchange of H₂ and O₂ on the “Ru(CO)₂(PPh₃)₂” moiety makes IV a catalyst not irreversibly poisoned by the presence of air. It has been found that even Ru(CO)₂(PPh₃)₃(II) acts as a catalyst for the isomerization of hex-1-ene at room temperature under an inert atmosphere.     

M(bpy)2+3(M=Fe,Ru,Os)电子结构与相关性质

报导了对配合物Ｍ（ｂｐｙ）＾２＋３（Ｍ＝Ｆｅ,Ｒｕ,Ｏｓ）的量子化学密度泛函法研究的结果。Ｂ３ＬＹＰ／ＬａｎＬ２ＤＺ方法与基组的水平上进行计算,探讨Ｍ（ｂｐｙ）＾２＋３电子结构特征及相关性质,特别是中心原子对配合物的配位键长、光谱性质,电荷布局及化学稳定性等的影响规律,为该类配合物的合成,为分析光、电、催化作用机理提供理论参考。     

Theoretical studies on the metathesis processes, (Tp(PH3)MR(eta 2-H[bond]CH3)]-->[Tp(PH3)M(CH3)(eta 2-H[bond]R)] (M=Fe,Ru, and Os; R=H and CH3)

Theoretical calculations on the metathesis process, [Tp(PH3)MR(eta 2-H[bond]CH3)] --> [Tp(PH3)M(CH3)(eta 2-H[bond]R)] (M=Fe, Ru, and Os; R=H and CH3), have been systematically carried out to study their detailed reaction mechanisms. Other than the one-step mechanism via a four-center transition state and the two-step mechanism through an oxidative addition/reductive elimination pathway, a new one-step mechanism, with a transition state formed under oxidative addition, has been found. Based on the intrinsic reaction coordinate calculations, we found that the trajectories of the transferring hydrogen atom in the metathesis processes studied are similar to each other regardless of the nature of reaction mechanisms.     

联吡啶钌配合物[Ru(Htcterpy)X3]3-[X=NCS,CN,Cl]的电子结构和光谱性质的理论研究

利用DFT中的B3LYP方法优化了3个联吡啶钌配合物[Ru(Htcterpy)X3]3-[tcterpy=4,4',4"-tricarboxy-2,2'∶6',2"-terpyridine, X=NCS(1), CN(2), Cl(3)]的基态几何结构, 得到的几何参数与实验结果吻合得很好. 采用TD-DFT方法, 得到了配合物1~3在气态和溶液(乙醇溶液和水溶液)中的激发态电子结构和电子吸收光谱. 利用SCRF方法中的CPCM模型来模拟溶剂化效应. 研究结果表明, 配合物1~3在气态和溶液中的吸收跃迁性质相似, 低能吸收均被指认为MLCT和LLCT的混合跃迁, 高能吸收均被指认为三联吡啶配体内的π→π*跃迁. 溶剂化效应使配合物1~3在溶液中的吸收光谱蓝移.     

Monosubstituted Trinuclear and Tetranuclear VIB Metal Carbonyl Complexes: Syntheses of [{M(CO)5}3(Pf-Pf-Pf)] [Pf-Pf-Pf = PhP(CH2CH2PPh2)2] and [{M(CO)5}4(P-Pf3)] [P-Pf3 = P(CH2CH2PPh2)3] (M = Cr,Mo) and Crystal Structures of the Latter Three

The triligate trimetallic complexes, [{M(CO)₅}₃(Pf-Pf-Pf)] and tetraligate tetrametallic complexes, [{M(CO)₅}₄(P-Pf₃)] (M = Cr and Mo), were prepared from [M(CO) ₆] and the corresponding ligands in MeCN/CH₂Cl₂ promoted by Me₃NO at 0 °C. Crystals of trimer lb are monoclinic, space group P 2₁/n, with a = 13.407(3), b = 15.002(5), c = 26.52(1) Å, β = 90.65(2)°, Z = 4, and R = 0.060 for 2760 observed reflections. Crystals of tetramer 2a are monoclinic, space group P 2₁/c, with a – 14.183(8), b = 29.880(4), c = 16.103(2) Å, β = 94.98(3)°, Z = 4, and R = 0.039 for 5014 observed reflections. Crystals of 2b are monoclinic, space group C 2/c, with a = 42.120(8), b = 13.679(1), c = 23.486(2) Å, β = 92.14(1)°, Z = 8, and R = 0.032 for 6897 observed reflections. Each phosphorus atom of the ligands is coordinated to the M(CO)₅ moiety in each title compounds. The geometry of the four metals is a distorted tetrahedron for the tetramers.