Madalan Augustin M, Avarvari Narcis, Fourmigué Marc, Clérac Rodolphe, Chibotaru Liviu F, Clima Sergiu, Andruh Marius
Inorganic Chemistry Laboratory, Faculty of Chemistry, University of Bucharest, Strausse Dumbrava Rosie nr. 23, 020464 Bucharest, Romania.
Inorg Chem. 2008 Feb 4;47(3):940-50. doi: 10.1021/ic701738z. Epub 2008 Jan 3.
New heterospin complexes have been obtained by combining the binuclear complexes [{Cu(H(2)O)L(1)}Ln(O(2)NO)(3)] or [{CuL(2)}Ln(O(2)NO)(3)] (L(1) = N,N'-propylene-di(3-methoxysalicylideneiminato); L(2) = N,N'-ethylene-di(3-methoxysalicylideneiminato); Ln = Gd(3+), Sm(3+), Tb(3+)), with the mononuclear [CuL(1)(2)] and the nickel dithiolene complexes Ni(mnt)(2)- (q = 1, 2; mnt = maleonitriledithiolate), as follows: (1)infinity[{CuL(1)}(2)Ln(O(2)NO){Ni(mnt)(2)}].Solv.CH(3)CN (Ln = Gd(3+), Solv = CH(3)OH (1), Ln = Sm(3+), Solv = CH(3)CN (2)) and [{(CH(3)OH)CuL(2)}(2)Sm(O(2)NO)][Ni(mnt)(2)] (3) with [Ni(mnt)2]2-, [{(CH(3)CN)CuL(1)}(2)Ln(H(2)O)][Ni(mnt)(2)]3.2CH(3)CN (Ln = Gd(3+) (4), Sm(3+) (5), Tb(3+) (6)), and [{(CH(3)OH)CuL(2)}{CuL(2)}Gd(O(2)NO){Ni(mnt)(2)}][Ni(mnt)(2)].CH(2)Cl(2) (7) with [Ni(mnt))(2]*-. Trinuclear, almost linear, [CuLnCu] motifs are found in all the compounds. In the isostructural 1 and 2, two trans cyano groups from a [Ni(mnt)2]2- unit bridge two trimetallic nodes through axial coordination to the Cu centers, thus leading to the establishment of infinite chains. 3 is an ionic compound, containing discrete {(CH(3)OH)CuL(2)}(2)Sm(O(2)NO) cations and Ni(mnt)(2) anions. Within the series 4-6, layers of discrete CuLnCu motifs alternate with stacks of interacting Ni(mnt)(2) radical anions, for which two overlap modes, providing two different types of stacks, can be disclosed. The strength of the intermolecular interactions between the open-shell species is estimated through extended Hückel calculations. In compound 7, Ni(mnt)(2) radical anions coordinate group one of the Cu centers of a trinuclear [Cu(2)Gd] motif through a CN, while discrete Ni(mnt)(2) units are also present, overlapping in between, but also with the coordinated ones. Furthermore, the [Cu(2)Gd] moieties dimerize each other upon linkage by two nitrato groups, both acting as chelate toward the gadolinium ion from one unit and monodentate toward a Cu ion from the other unit. The magnetic properties of the gadolinium-containing complexes have been determined. Ferromagnetic exchange interactions within the trinuclear [Cu(2)Gd] motifs occur. In the compounds 4 and 7, the Ni(mnt)(2) radical anions contribution to the magnetization is clearly observed in the high-temperature regime, and most of it vanishes upon temperature decrease, very likely because of the rather strong antiferromagnetic exchange interactions between the open-shell species. The extent of the exchange interaction in the compound 7, which was found to be antiferromagnetic, between the coordinated Cu center and the corresponding Ni(mnt)(2) radical anion, bearing mostly a 3p spin type, was estimated through CASSCF/CASPT2 calculations. Compound 6 exhibits a slow relaxation of the magnetization.
通过将双核配合物[{Cu(H₂O)L₁}Ln(O₂NO)₃]或[{CuL₂}Ln(O₂NO)₃](L₁ = N,N'-亚丙基-二(3-甲氧基水杨醛亚胺基);L₂ = N,N'-亚乙基-二(3-甲氧基水杨醛亚胺基);Ln = Gd³⁺、Sm³⁺、Tb³⁺)与单核[CuL₁₂]和镍二硫纶配合物[Ni(mnt)₂]q⁻(q = 1, 2;mnt = 马来腈二硫醇盐)相结合,得到了新的异自旋配合物,如下所示:(1)∞[{CuL₁}₂Ln(O₂NO){Ni(mnt)₂}].Solv.CH₃CN(Ln = Gd³⁺,Solv = CH₃OH (1),Ln = Sm³⁺,Solv = CH₃CN (2))以及[{(CH₃OH)CuL₂}₂Sm(O₂NO)][Ni(mnt)₂] (3) 与[Ni(mnt)₂]²⁻,[{(CH₃CN)CuL₁}₂Ln(H₂O)][Ni(mnt)₂]·3.2CH₃CN(Ln = Gd³⁺ (4),Sm³⁺ (5),Tb³⁺ (6)),以及[{(CH₃OH)CuL₂}{CuL₂}Gd(O₂NO){Ni(mnt)₂}][Ni(mnt)₂]·CH₂Cl₂ (7) 与[Ni(mnt)₂]·⁻。在所有化合物中都发现了三核、近似线性的[CuLnCu]结构单元。在同构的1和2中,来自[Ni(mnt)₂]²⁻单元的两个反式氰基通过与Cu中心的轴向配位桥连两个三金属节点,从而形成无限链。3是一种离子化合物,包含离散的[{(CH₃OH)CuL₂}₂Sm(O₂NO)]²⁺阳离子和[Ni(mnt)₂]²⁻阴离子。在系列4 - 6中,离散的[CuLnCu]³⁺结构单元层与相互作用的[Ni(mnt)₂]⁻自由基阴离子堆叠交替出现,对于后者可以揭示两种重叠模式,提供两种不同类型的堆叠。通过扩展休克尔计算估计了开壳物种之间分子间相互作用的强度。在化合物7中,[Ni(mnt)₂]⁻自由基阴离子通过一个CN配位到三核[Cu₂Gd]结构单元的一个Cu中心,同时也存在离散的[Ni(mnt)₂]⁻单元,它们相互重叠,也与配位的单元重叠。此外,[Cu₂Gd]部分通过两个硝酸根基团相互二聚,这两个硝酸根基团对一个单元中的钆离子都起螯合作用,对另一个单元中的Cu离子起单齿作用。已测定了含钆配合物的磁性。在三核[Cu₂Gd]结构单元内发生铁磁交换相互作用。在化合物4和7中,在高温区域清楚地观察到[Ni(mnt)₂]⁻自由基阴离子对磁化的贡献,并且随着温度降低大部分贡献消失,很可能是由于开壳物种之间相当强的反铁磁交换相互作用。通过CASSCF/CASPT2计算估计了化合物7中配位的Cu中心与相应的[Ni(mnt)₂]⁻自由基阴离子之间的交换相互作用程度,发现其为反铁磁,该自由基阴离子主要具有3p自旋类型。化合物6表现出磁化的缓慢弛豫。
