Adamovic Ivana, Gordon Mark S
Department of Chemistry, Iowa State University, Ames, Iowa 50011, USA.
J Phys Chem A. 2005 Mar 3;109(8):1629-36. doi: 10.1021/jp040665d.
The performance of the density functional theory (DFT)-based effective fragment potential (EFP) method is assessed using the S(N)2 reaction: Cl- + nH2O + CH3Br = CH3Cl + Br- + nH2O. The effect of the systematic addition of water molecules on the structures and relative energies of all species involved in the reaction has been studied. The EFP1 method is compared with second-order perturbation theory (MP2) and DFT results for n = 1, 2, and 3, and EFP1 results are also presented for four water molecules. The incremental hydration effects on the barrier height are the same for all methods. However, only full MP2 or MP2 with EFP1 solvent molecules are able to provide an accurate treatment of the transition state (TS) and hence the central barriers. Full DFT and DFT with EFP1 solvent molecules both predict central barriers that are too small. The results illustrate that the EFP1-based DFT method gives reliable results when combined with an accurate quantum mechanical (QM) method, so it may be used as an efficient alternative to fully QM methods in the treatment of larger microsolvated systems.
利用S(N)2反应:Cl- + nH2O + CH3Br = CH3Cl + Br- + nH2O,对基于密度泛函理论(DFT)的有效片段势(EFP)方法的性能进行了评估。研究了系统添加水分子对反应中所有物种的结构和相对能量的影响。将EFP1方法与二阶微扰理论(MP2)和n = 1、2和3时的DFT结果进行了比较,还给出了四个水分子时的EFP1结果。所有方法对势垒高度的增量水合效应都是相同的。然而,只有完整的MP2或带有EFP1溶剂分子的MP2能够准确处理过渡态(TS),从而准确处理中心势垒。完整的DFT和带有EFP1溶剂分子的DFT都预测中心势垒过小。结果表明,基于EFP1的DFT方法与精确的量子力学(QM)方法结合时能给出可靠的结果,因此在处理更大的微溶剂化体系时,它可以作为完全QM方法的一种有效替代方法。
