双核配合物[Cu2(TS)(H2O)]·CH3OH的自组装制备和晶体结构

The binuclear complex [Cu₂(TS)(H₂O)]·CH₃OH, where TS denotes the binucleating ligand derived from the schiff base N,N′-bis(3-carboxylsalidene)trimethylenediamine, was obtained from the self-decomposition of mononuclear complex Na₂CuTS·H₂O. It crystallizes in the monoclinic system, space group P2₁/c. The lattice parameters are a=11.935(2)?,b=15.667(3)?,c=11.621(2)?,β=111.60(3)°,V=2020.2(7)?³, Z=4 with R=0.0467. The structure is made of binuclear units, in which two copper atoms are bridged by two phenolic oxygen atoms. The “inside”copper atom is coordinated by two nitrogens, two phenolic oxygens in a planar coordi-nation site, the copper atom deviates from the mean plane by 0.47?. The “outside” copper atom is five coordinated by two phenolic oxygen atoms、two equatorial carboxyl oxygen atoms and one axial water oxygen atom in a distorted tetragonal cone site, the copper atom is pulled out of the equatorial plane by 0.46?.     

N-(2-羧基苯)-N’-(3-氨丙基)草酰胺桥联异双核配合物的合成、电化学性质和磁性

合成了 4种不对称草酰胺桥联异双核配合物 [Cu( oxca) M( phen) 2 ]Cl O4· 2 H2 O[oxca表示 N -( 2 -羧基苯 ) -N -( 3-氨丙基 )草酰胺三价阴离子 ,phen代表邻菲啉 ,M=Mn、Co、Ni、Zn].用元素分析、红外光谱、电子光谱、热分析及室温磁矩等对所合成配合物进行了表征 .在 DMSO溶剂中采用循环伏安法研究了配合物的电化学性质 .在 4～ 30 0 K范围测量了 Cu( ) -Mn( )和 Cu( ) -Ni( )的变温磁化率 ,经拟合分别得磁参数 J=-1 0 .5 6 cm- 1 和 J=-1 7.0 8cm- 1 ,表明在异双核配合物中金属离子间有较弱的反铁磁性自旋交换作用 .     

草酰胺桥联大环二羰四胺铜(Ⅱ)-钴(Ⅱ)异双核配合物的合成、结构、表征和电化学性质

合成了一种具有草酰胺桥联大环二羰四胺结构的 Cu( ) -Co( )异双核配合物 ,用红外光谱、电子光谱、摩尔电导、热重分析、室温磁矩、循环伏安等对其进行了表征 .初步推定 Cu( ) -Co( )异双核配合物具有草酰胺桥联大环二羰四胺结构 .室温磁矩测定表明 ,通过草酰胺桥联配体金属离子间有一定的反铁磁性自旋偶合作用 .循环伏安法测定了配合物的半波电位 ,实验表明 ,此类配合物能够稳定高价态 Cu( ) ,外延桥基配位对大环内腔 Cu( )离子的氧化还原过程无影响 .单核配合物 X射线晶体衍射研究表明 ,其为单斜晶系 ,空间群 P2 1 /c,a=0 .73 861 (1 5 ) nm,b=2 .1 2 1 1 (4 ) nm,c=0 .95 2 5 0 (1 9) nm,β=94.70 (3 )°,R1 =0 .0 5 1 3 ,w R2 =0 .1 1 77,Z=4.Cu( )处于大环四胺平面正方中心上方 0 .0 3 nm,并具有外延草酰胺桥     

N,N′- 双(3-羧基水杨醛叉缩胺乙基)草酰胺均双核铜(Ⅱ),镍(Ⅱ)配合物合成和性能研究

近来发现草酰胺具有多原子成桥功能,Kahn和廖代正等人^[1,2]设计合成一些对称和不对称草酰桥联的双核及多核配合物,并对其性质进行研究,本文报导N,N'-双（3－羧基水杨醛叉缩胺乙基）草酰胺配体及其铜（II）,镍（II）均双核配合物的合成和表征,及铜双核配合物的电化学性能研究。     

N，N＇-双(3-羧基水杨醛叉缩胺乙基)草酰胺均双核铜(Ⅱ)，镍(Ⅱ)配合物合成和性能研究

The homobinuclear complexes of Cu (Ⅱ) and Ni (Ⅱ) with N, N＇-bis(3-Carboxyl salicyl aminal ethylene) oxalamide were synthesized, and characterized by elemental analysis, IR spectra, Uv-visible spectra, conductometry, thermogravimetry, and magnetic susceptibility measurement, which indicated the complexes own an oxalic amide bridge-linking structure. Room temperature magnetic moment data show that there are antiferromagnetic spin coupling through oxalic amide conjugated double bond, In DMF, the redox half wave potential of Cu (Ⅱ) binuclear complexes have been measured by cyclic voltammetry, which proves that the Cu (Ⅱ) complex has two redox waves.     

新型草酰胺桥联Cu(Ⅱ),Ni(Ⅱ)均双核配合物的合成及表征

合成了一种新配体N ,N′ 二 (2 氨乙基 ) 草酰胺双缩邻氨基苯甲醛Schiff碱 (H4L)及其Cu(Ⅱ )、Ni(Ⅱ )均双核配合物。并用元素分析、红外光谱、电子光谱、室温磁化率等对其组成和结构进行表征。室温磁矩表明配合物中两金属离子间通过草酰胺桥存在着反铁磁性自旋偶合作用。     

两种不对称草酰胺桥联双核铜(Ⅱ)配合物的合成及电化学性质

合成了两种新型草酰胺桥联双核铜配合物 ,并以元素分析、红外光谱、电子光谱、摩尔电导、热重分析和室温磁矩对所合成铜配合物进行表征 ,推定新合成的双核铜配合物具有草酰胺桥联结构 .采用循环伏安法测定了双核配合物的氧化还原电位 ,表明两种配合物均显示一个单电子还原过程 .     

草酰胺桥联异三核配合物的电化学及磁学性质

异三核草酰胺桥联配合物;循环伏安法;反铁磁作用;草酰胺桥联异三核配合物的电化学及磁学性质     

异双核配合物[CuCo(TS)(H2O)]·H2O的晶体结构和热分析性质研究

The single-crystal of [CuCo(TS)(H₂O)·H₂O],where TS is the schiff base N,N＇-bis(3-carboxylsalidene)trimethylenediamine, was obtained and its crystal structure was determined by the single-crystal X-ray diffraction method at room temperature. It crystallizes in the monoclinic system, space group P2₁/c. The lattice parameters are a=11.855(2)?, b=14.722(3)?, c=12.080(2)?, β=117.32(3)°, V=1879.4(7)?³ , Z=4 with R₁=0.0330. The structure is made of heterobinuclear units . The copper atom is coordinated by two nitrogens, two phenolic oxygens, in a square-planar manner. And the cobalt atom is coordinated by two phenolic oxygen atoms, two equatorial carboxyl oxygen atoms and one axial water oxygen atom, in a distorted square pyramid. Two metal atoms are bridged by two phenolic oxygens. In the crystal packing, the neutral molecules built layers. Within these layers the molecules are connected through hydrogen bonds. And the thermal property of the complex according to crystal structure is also investigated.