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化学学报
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化学学报 ›› 2010, Vol. 68 ›› Issue (06): 493-500. 上一篇    下一篇

研究论文

CH3SH和CH3SLi分子间的锂键和氢键共存型相互作用

刘艳芝1,施小宁1,唐慧安1,刘新文1,袁焜*,1,张俊彦2,张继3   

  1. (1天水师范学院生命科学与化学学院 天水 741001)
    (2中国科学院兰州化学物理研究所 兰州 730000)
    (3西北师范大学生命科学学院 兰州 730000)
  • 投稿日期:2008-11-26 修回日期:2009-09-22 发布日期:2010-03-28
  • 通讯作者: 刘艳芝 E-mail:lyanzhi003@163.com
  • 基金资助:

    和甘肃省教育厅研究生导师科研基金(批准号: NO. 07-08-12);天水师范学院“青蓝”人才工程基金资助.

Co-Existing Lithium Bonding and Hydrogen Bonding Interactions between CH3SH and CH3SLi

Liu Yanzhi1 Shi Xiaoning1 Tang Huian1 Liu Xinwen1 Yuan Kun*,1 Zhang Junyan2 Zhang Ji3   

  1. (1 College of Life Science and Chemistry, Tianshui Normal University, Tianshui 741001)
    (2 Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences, Lanzhou 730000)
    (3 College of Life Science, Northwest Normal University, Lanzhou 730070)
  • Received:2008-11-26 Revised:2009-09-22 Published:2010-03-28

在CH3SLi+CH3SH势能面上求得锂键和氢键共存型复合物的两种稳定构型. 频率分析表明, 与单体相比复合物中S(5)—Li(6)键伸缩振动频率发生红移, 而C(8)—H(10)键伸缩振动频率发生蓝移. 经B3LYP/6-311++G**, MP2/6-311++G**及MP2/AUG-CC-PVDZ水平计算的含基组重叠误差(BSSE)校正的复合物?中相互作用能分别为-58.99, -57.87和-62.89 kJ•mol-1. 采用自然键轨道(NBO)理论, 分析了复合物中单体轨道间的电荷转移, 电子密度重排及其与相关键键长变化的本质等. 采用分子中的原子(AIM)理论分析了复合物中氢键和锂键的电子密度拓扑性质.在极化连续模型(PCM)下, 考察了溶剂化效应. 结果表明, 所考察的水、二甲亚砜、乙醇和乙醚等四种溶剂均使单体间的相互作用能增大, 且溶剂对复合物中的锂键结构及其振动频率具有显著的影响, 而对复合物中的氢键的振动频率影响不大.

关键词: 甲硫醇锂, 氢键和锂键共存, 自然键轨道理论, 分子中原子理论, 溶剂化效应

The two optimized stable lithium bonding and hydrogen bonding co-existing complexes, CH3SLi…CH3SH, were found on the potential energy surface of CH3SLi+CH3SH. Red shift of the S(5)—Li(6) and blue shift of C(8)—H(10) stretching vibrational frequencies were obtained simultaneously via frequency analysis. The BSSE-corrected interaction energies in complex ? obtained by using B3LYP/6-311++G**, MP2/6-311++G** and MP2/AUG-CC-PVDZ were -58.99, -57.87 and -62.89 kJ•mol-1, respectively. From the natural bond orbital (NBO) analysis, The charge transfer interactions between the related orbits, electron density redistributions and the essential of the correlative bond length changes in the complexes were detailedly discussed. The topological properties of the hydrogen bond and lithium bond structures were also investigated by the atoms-in-molecules (AIM) theory. In addition, the solvent effects were studied using the polarized continuum model (PCM). The results showed that the interaction energy would increase in the presence of solvents, and the solvents could evidently affect the geometric structure and vibration frequency of the lithium bond in CH3SLi…CH3SH, but not obviously the frequency of the hydrogen bond.

Key words: CH3SLi, co-existing of lithium bond and hydrogen bond, natural bond orbital theory, atoms-in-molecules theory, solvent effect

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