Hirota Shun, Polson Suzette M., Puckett James M., Moore Scott J., Mitchell Mark B., Marzilli Luigi G.
Departments of Chemistry, Emory University, Atlanta, Georgia 30322, and Clark Atlanta University, Atlanta, Georgia 30314.
Inorg Chem. 1996 Sep 11;35(19):5646-5653. doi: 10.1021/ic9602613.
Near-IR FT-Raman spectroscopy was used to probe the properties of three types of methyl imine/oxime B(12) model compounds in CHCl(3) solution. These types differ in the nature of the 1,3-propanediyl chain and were selected to test the influence of electronic and steric effects on the Co-CH(3) stretching (nu(Co)(-)(CH)()3) frequency, a parameter related to Co-C bond strength. For the first type studied, LCo((DO)(DOH)pn)CH(3) ((DO)(DOH)pn = N(2),N(2)(')-propane-1,3-diylbis(2,3-butanedione 2-imine 3-oxime)), nu(Co)(-)(CH)()3 decreased from 505 to 455 cm(-)(1) with stronger electron-donating character of the trans axial ligand, L, in the order Cl(-), MeImd, Me(3)Bzm, 4-Me(2)Npy, py, 3,5-Me(2)PhS(-), PMe(3), and CD(3)(-). This series thus allows the first assessment of the effect of negative axial ligands on nu(Co)(-)(CH)()3; these ligands (L = Cl(-), 3,5-Me(2)PhS(-), CD(3)(-)) span the range of trans influence. The CH(3) bending (delta(CH3)) bands were observed at 1171, 1159, and 1150/1105 cm(-)(1), respectively. The decrease in C-H stretching frequencies (nu(CH)) of the axial methyl suggests that the C-H bond strength decreases in the order Cl(-) > 3,5-Me(2)PhS(-) > CD(3)(-). This result is consistent with the order of decreasing (13)C-(1)H NMR coupling constants obtained for the axial methyl group. The trend of lower nu(Co)(-)(CH)()3 and nu(CH) frequencies and lower axial methyl C-H coupling constant for stronger electron-donating trans axial ligands can be explained by changes in the electronic character of the Co-C bond. The symmetric CH(3)-Co-CH(3) mode (nu(CH)()3(-)(Co)(-)(CH)()3) for (CH(3))(2)Co((DO)(DOH)pn) was determined to be 456 cm(-)(1) (421 cm(-)(1) for (CD(3))(2)Co((DO)(DOH)pn). The L-Co-CH(3) bending mode (delta(L)(-)(Co)(-)(CH)()3) was detected for the first time for organocobalt B(12) models; this mode, which is important for force field calculations, occurs at 194 cm(-)(1) for ClCo((DO)(DOH)pn)CH(3) and at 186 cm(-)(1) for (CH(3))(2)Co((DO)(DOH)pn. The nu(Co)(-)(CH)()3 frequencies were all lower than those reported for the corresponding cobaloxime type LCo(DH)(2)CH(3) (DH = monoanion of dimethylglyoxime) models for planar N-donor L. This relationship is attributed to a steric effect of L in LCo((DO)(DOH)pn)CH(3). The puckered 1,3-propanediyl chain in LCo((DO)(DOH)pn)CH(3) forces the planar L ligands to adopt a different orientation compared to that in the cobaloxime models. The consequent steric interaction bends the equatorial ligand toward the methyl group (butterfly bending); this distortion leads to a longer Co-C bond. In a second imine/oxime type, a pyridyl ligand is connected to the 1,3-propanediyl chain and oriented so as to minimize butterfly bending. The nu(Co)(-)(CH)()3 frequency for this new lariat model was close to that of pyCo(DH)(2)CH(3). In a third type, a bulkier 2,2-dimethyl-1,3-propanediyl group replaces the 1,3-propanediyl chain. The nu(Co)(-)(CH)()3 bands for two complexes with L = Me(3)Bzm and py were 2-5 cm(-)(1) lower in frequency than those of the corresponding L(Co((DO)(DOH)pn)CH(3) complexes. The decrease in the axial nu(Co)(-)(CH)()3 frequencies is probably due to the steric effect of the equatorial ligand. Thus, the nu(Co)(-)(CH)()3 frequency can be useful for investigating both steric and electronic influences on the Co-C bond.
采用近红外傅里叶变换拉曼光谱法研究了三种甲基亚胺/肟型维生素B12模型化合物在CHCl₃溶液中的性质。这三种类型在1,3 - 丙二基链的性质上有所不同,被选来测试电子效应和空间效应对Co - CH₃伸缩振动(ν(Co)(-)(CH)₃)频率的影响,该参数与Co - C键强度相关。对于研究的第一种类型,LCo((DO)(DOH)pn)CH₃((DO)(DOH)pn = N(2),N(2)'-丙烷 - 1,3 - 二基双(2,3 - 丁二酮2 - 亚胺3 - 肟)),随着反式轴向配体L的给电子能力增强,ν(Co)(-)(CH)₃从505 cm⁻¹降至455 cm⁻¹,顺序为Cl⁻、MeImd、Me₃Bzm、4 - Me₂Npy、py、3,5 - Me₂PhS⁻、PMe₃和CD₃⁻。因此,该系列首次评估了负轴向配体对ν(Co)(-)(CH)₃的影响;这些配体(L = Cl⁻、3,5 - Me₂PhS⁻、CD₃⁻)涵盖了反式影响的范围。CH₃弯曲(δ(CH₃))带分别在1171、1159和1150/1105 cm⁻¹处观察到。轴向甲基的C - H伸缩频率(ν(CH))降低表明C - H键强度按Cl⁻ > 3,5 - Me₂PhS⁻ > CD₃⁻的顺序降低。该结果与轴向甲基获得的¹³C - ¹H NMR耦合常数降低顺序一致。对于给电子能力更强的反式轴向配体,较低的ν(Co)(-)(CH)₃和ν(CH)频率以及较低的轴向甲基C - H耦合常数趋势可以通过Co - C键电子性质的变化来解释。(CH₃)₂Co((DO)(DOH)pn)的对称CH₃ - Co - CH₃模式(ν(CH)₃(-)(Co)(-)(CH)₃)确定为456 cm⁻¹((CD₃)₂Co((DO)(DOH)pn)为421 cm⁻¹)。首次在有机钴维生素B12模型中检测到L - Co - CH₃弯曲模式(δ(L)(-)(Co)(-)(CH)₃);该模式对于力场计算很重要,对于ClCo((DO)(DOH)pn)CH₃在194 cm⁻¹处出现,对于(CH₃)₂Co((DO)(DOH)pn)在186 cm⁻¹处出现。对于平面N - 供体L,所有的ν(Co)(-)(CH)₃频率都低于相应的钴肟型LCo(DH)₂CH₃(DH = 二甲基乙二肟单阴离子)模型报道的频率。这种关系归因于LCo((DO)(DOH)pn)CH₃中L的空间效应。LCo((DO)(DOH)pn)CH₃中褶皱的1,3 - 丙二基链迫使平面L配体与钴肟模型中的配体采取不同的取向。随之产生的空间相互作用使赤道配体向甲基弯曲(蝶形弯曲);这种扭曲导致Co - C键更长。在第二种亚胺/肟类型中,一个吡啶基配体连接到1,3 - 丙二基链上并取向以最小化蝶形弯曲。这种新的套索模型的ν(Co)(-)(CH)₃频率接近pyCo(DH)₂CH₃的频率。在第三种类型中,一个更大的2,2 - 二甲基 - 1,3 - 丙二基取代了1,3 - 丙二基链。对于L = Me₃Bzm和py的两种配合物,其ν(Co)(-)(CH)₃带的频率比相应的L(Co((DO)(DOH)pn)CH₃配合物低2 - 5 cm⁻¹。轴向ν(Co)(-)(CH)₃频率的降低可能是由于赤道配体的空间效应。因此,ν(Co)(-)(CH)₃频率可用于研究空间和电子对Co - C键的影响。
