Hervé Alexandre, Bouzidi Yamina, Berthet Jean-Claude, Belkhiri Lotfi, Thuéry Pierre, Boucekkine Abdou, Ephritikhine Michel
CEA, IRAMIS, NIMBE, UMR 3299 CEA/CNRS SIS2M, CEA/Saclay , Bat 125, 91191 Gif-sur-Yvette, France.
Inorg Chem. 2014 Jul 7;53(13):6995-7013. doi: 10.1021/ic500939t. Epub 2014 Jun 16.
Reactions of [MN3] (M = Ce, U; N = N(SiMe3)2) and NR4CN (R = Me, Et, or (n)Bu) or KCN in the presence of 18-crown-6 afforded the series of cyanido-bridged dinuclear compounds [NEt4][(MN3)2(μ-CN)] (M = Ce, 2a, and U, 2b), [K(18-crown-6)(THF)2][(CeN3)2(μ-CN)] (2'a), and [K(18-crown-6)][(UN3)2(μ-CN)] (2'b), and the mononuclear mono-, bis-, and tris(cyanide) complexes [NEt4][MN3(CN)] (M = Ce, 1a(Et), and U, 1b(Et)), [NMe4][MN3(CN)] (M = Ce, 1a(Me), and U, 1b(Me)), [K(18-crown-6)][MN3(CN)] (M = Ce, 1'a, and U, 1'b), [N(n)Bu4]2[MN3(CN)2] (M = Ce, 3a, and U, 3b), [K(18-crown-6)]2[MN3(CN)2] (M = Ce, 3'a, and U, 3'b), and [N(n)Bu4]2[MN2(CN)3] (M = Ce, 4a, and U, 4b). The mono- and bis(cyanide) complexes were found to be in equilibrium. The formation constant of 3'b (K3'b) from 1'b at 10 °C in THF is equal to 5(1) × 10(-3), and -ΔH3'b = 104(2) kJ mol(-1) and -ΔS3'b = 330(5) J mol(-1) K(-1). The bis(cyanide) compound 3a or 3b was slowly transformed in solution into an equimolar mixture of the mono- and tris(cyanide) derivatives with elimination of N(n)Bu4N. The crystal structures of 1a(Me), 1b(Me), 1'a·toluene, 1'b·toluene, 2'a, 2'b, 3a, 3'a, 3'b, 3'a·2benzene, 3'b·2benzene, 4a·0.5THF, and 4b·Et2O were determined. Crystals of the bis(cyanide) uranium complexes 3'b and 3'b·2benzene are isomorphous with those of the cerium counterparts 3'a and 3'a·2benzene, but they are not isostructural since the data revealed distinct coordination modes of the CN group, through the C or N atom to the U or Ce metal center, respectively. This differentiation has been analyzed using density functional theory calculations. The observed preferential coordination of the cyanide and isocyanide ions toward uranium or cerium in the bis(cyanide) complexes is corroborated by the consideration of the binding energies of these groups to the metals and by the comparison of DFT optimized geometries with the crystal structures. The better affinity of the cyanide ligand toward U(III) over Ce(III) metal center is related to the better energy matching between the 6d/5f uranium orbitals and the cyanide ligand ones, leading to a non-negligible covalent character of the bonding.
在18 - 冠 - 6存在的情况下,[MN₃](M = Ce,U;N = N(SiMe₃)₂)与NR₄CN(R = Me,Et或(n)Bu)或KCN反应,得到了一系列氰基桥联双核化合物[NEt₄][(MN₃)₂(μ - CN)](M = Ce,2a,和U,2b)、[K(18 - 冠 - 6)(THF)₂][(CeN₃)₂(μ - CN)](2'a)和[K(18 - 冠 - 6)][(UN₃)₂(μ - CN)](2'b),以及单核单氰化物、双氰化物和三氰化物配合物[NEt₄][MN₃(CN)](M = Ce,1a(Et),和U,1b(Et))、[NMe₄][MN₃(CN)](M = Ce,1a(Me),和U,1b(Me))、[K(18 - 冠 - 6)][MN₃(CN)](M = Ce,1'a,和U,1'b)、[N(n)Bu₄]₂[MN₃(CN)₂](M = Ce,3a,和U,3b)、[K(18 - 冠 - 6)]₂[MN₃(CN)₂](M = Ce,3'a,和U,3'b)和[N(n)Bu₄]₂[MN₂(CN)₃](M = Ce,4a,和U,4b)。发现单氰化物和双氰化物配合物处于平衡状态。在10℃的THF中,由1'b形成3'b的形成常数K₃'b等于5(1)×10⁻³,-ΔH₃'b = 104(2) kJ mol⁻¹,-ΔS₃'b = 330(5) J mol⁻¹ K⁻¹。双氰化物化合物3a或3b在溶液中缓慢转化为单氰化物和三氰化物衍生物的等摩尔混合物,并消除N(n)Bu₄N。测定了1a(Me)、1b(Me)、1'a·甲苯(1'a与甲苯)、1'b·甲苯(1'b与甲苯)、2'a、2'b、3a、3'a、3'b、3'a·2苯(3'a与2个苯分子)、3'b·2苯(3'b与2个苯分子)、4a·0.5THF(4a与0.5个THF分子)和4b·Et₂O(4b与乙醚)的晶体结构。双氰化物铀配合物3'b和3'b·2苯的晶体与铈对应物3'a和3'a·2苯的晶体同晶,但它们不是同结构的,因为数据显示CN基团分别通过C或N原子与U或Ce金属中心的不同配位模式。已使用密度泛函理论计算分析了这种差异。通过考虑这些基团与金属的结合能以及将DFT优化的几何结构与晶体结构进行比较,证实了在双氰化物配合物中观察到的氰化物和异氰化物离子对铀或铈的优先配位。氰化物配体对U(III)金属中心的亲和力优于Ce(III)金属中心,这与6d/5f铀轨道和氰化物配体轨道之间更好的能量匹配有关,导致键具有不可忽略的共价性质。
