Singh Ngangbam Bedamani, Sarkar Utpal
Department of Physics, Assam University, Silchar, 788011, India.
J Mol Model. 2014 Dec;20(12):2537. doi: 10.1007/s00894-014-2537-5. Epub 2014 Dec 2.
Using density functional theory, stability, chemical, and optical properties of small platinum clusters, Ptn (n = 2 to 10) have been investigated. An attempt has been made to establish a correlation between stability and chemical reactivity parameters. The calculated geometries are in agreement with the available experimental and theoretical results. The atom addition energy change (ΔE1) and stability function (ΔE2) reveal that Pt7 is more stable than its neighboring clusters. Very good agreement of the calculated electron affinity with the available experimental results has been observed. The polarizability of the Ptn clusters depends almost linearly on the number of atoms. A correlation between the static polarizability and ionization potential is found, paving a way to calculate polarizabilty of larger clusters from their ionization potential. The calculated vibrational frequencies are compared with available experimental and theoretical results and good agreement between them has been established. In general, the prominent peak of molar absorption coefficient is shifting toward the lower energy side when cluster size grows. Our DOS calculation suggests that d orbital is primarily responsible for HOMO position and s orbital is responsible for LUMO position.
利用密度泛函理论,对小铂团簇Ptn(n = 2至10)的稳定性、化学性质和光学性质进行了研究。已尝试建立稳定性与化学反应性参数之间的相关性。计算得到的几何结构与现有的实验和理论结果一致。原子添加能量变化(ΔE1)和稳定性函数(ΔE2)表明,Pt7比其相邻团簇更稳定。计算得到的电子亲和能与现有实验结果非常吻合。Ptn团簇的极化率几乎与原子数呈线性关系。发现了静态极化率与电离势之间的相关性,为从其电离势计算更大团簇的极化率铺平了道路。将计算得到的振动频率与现有的实验和理论结果进行了比较,并在它们之间建立了良好的一致性。一般来说,当团簇尺寸增大时,摩尔吸收系数的突出峰值向低能量侧移动。我们的态密度计算表明,d轨道主要负责最高占据分子轨道(HOMO)的位置,s轨道负责最低未占据分子轨道(LUMO)的位置。