Center for Computational Materials Science, Naval Research Laboratory, Washington, DC 20375-5341, United States.
J Phys Chem A. 2011 Nov 17;115(45):12445-50. doi: 10.1021/jp203913n. Epub 2011 Jul 25.
We investigate anew the possible equilibrium geometries of ion induced dipole clusters of hydrogen molecular ions, of molecular formula H(n)(-) (3 ≤ n-odd ≤ 13). Our previous publications [Sapse, A. M.; et al. Nature 1979, 278, 332; Rayez, J. C.; et al., J. Chem. Phys. 1981, 75, 5393] indicated these molecules would have a shallow minimum and adopt symmetrical geometries that accord with the valence shell electron pair repulsion (VSEPR) rules for geometries defined by electron pairs surrounding a central point of attraction. These earlier calculations were all based upon Hartree-Fock (HF) calculations with a fairly small basis of atomic functions, except for the H3(-) ion for which configuration interaction (CI) calculations were carried out. A related paper [Hirao, K.; et al., Chem. Phys. 1983, 80, 237] carried out similar calculations on the same clusters, finding geometries similar to our earlier calculations. However, although that paper argued that the stabilization energy of negative ion clusters H(n)(-) is small, vibration frequencies for the whole set of clusters was not reported, and so a definitive assertion of a true equilibrium was not present. In this paper we recalculate the energetics of the ion induced dipole clusters using density function theory (DFT) B3LYP method calculations in a basis of functions (6-311++G(d,p)). By calculating the vibration frequencies of the VSEPR geometries, we prove that in general they are not true minima because not all the resulting frequencies correspond to real values. By searching the energy surface of the B3LYP calculations, we find the true minimum geometries, which are surprising configurations and are perhaps counterintuitive. We calculate the total energy and binding energy of the new geometries. We also calculate the bond paths associated with the quantum theory of atoms in molecules (QTAIM). The B3LYP/6-311++G(d,p) results, for each molecule, deliver bond paths that radiate between each polarized H2 molecule and the polarizing H(-) ion.
我们重新研究了氢分子离子离子诱导偶极子簇 H(n)(-)(3 ≤ n-odd ≤ 13)的可能平衡几何形状。我们之前的出版物[Sapse, A. M.; 等人。自然 1979, 278, 332; Rayez, J. C.; 等人,J. Chem. Phys. 1981, 75, 5393]表明这些分子将具有浅的最小值,并采用与价层电子对排斥(VSEPR)规则一致的对称几何形状,这些规则适用于围绕中心吸引力点的电子对定义的几何形状。这些早期的计算都是基于 Hartree-Fock (HF) 计算,除了 H3(-) 离子外,原子函数的基础都相当小,对于 H3(-) 离子,进行了组态相互作用 (CI) 计算。一篇相关的论文[Hirao, K.; 等人,化学物理 1983, 80, 237]对相同的簇进行了类似的计算,发现与我们早期的计算相似的几何形状。然而,尽管该论文认为负离子簇 H(n)(-) 的稳定能很小,但未报告整个簇的振动频率,因此没有给出真正平衡的明确断言。在本文中,我们使用密度泛函理论(DFT)B3LYP 方法在函数(6-311++G(d,p))的基础上重新计算了离子诱导偶极子簇的能量。通过计算 VSEPR 几何形状的振动频率,我们证明它们通常不是真正的最小值,因为并非所有得到的频率都对应于实数值。通过搜索 B3LYP 计算的能量表面,我们找到了真正的最小几何形状,这些形状是令人惊讶的配置,可能违反直觉。我们计算了新几何形状的总能量和结合能。我们还计算了与分子中原子量子理论(QTAIM)相关的键路径。对于每个分子,B3LYP/6-311++G(d,p) 的结果都提供了在每个极化 H2 分子和极化 H(-) 离子之间辐射的键路径。
