Sinha Ray Suvonil, Ghosh Anirban, Chattopadhyay Sudip, Chaudhuri Rajat K
Department of Chemistry, Indian Institute of Engineering Science and Technology, Shibpur , Howrah 711103, India.
Theoretical Physics, Indian Institute of Astrophysics , Bangalore 560034, India.
J Phys Chem A. 2016 Jul 28;120(29):5897-916. doi: 10.1021/acs.jpca.6b03211. Epub 2016 Jul 13.
Recently a state-specific multireference perturbation theory (SSMRPT) with an improved virtual orbitals complete active space configuration interaction (IVO-CASCI) reference function has been proposed for treating electronic structures of radicals such as methylene, m-benzyne, pyridyne, and pyridynium cation. This new development in MRPT, termed as IVO-SSMRPT, ensures that it is able to describe the structure of radicaloids with reasonable accuracy even with small reference spaces. IVO-SSMRPT is also capable of predicting the correct ordering of the lowest singlet-triplet gaps. Investigation of the first three electronic states of the oxygen molecule has also been used for rating our method. The agreement of our estimates with the available far more expensive benchmark state-of-the-art ab initio calculations is creditable. The IVO-SSMRPT method provides an effective avenue with manageable cost/accuracy ratio for accurately dealing with radicaloid systems possessing varying degrees of quasidegeneracy.
最近,一种具有改进的虚拟轨道完全活性空间组态相互作用(IVO-CASCI)参考函数的特定状态多参考微扰理论(SSMRPT)被提出来用于处理诸如亚甲基、间位苯炔、吡啶炔和吡啶鎓阳离子等自由基的电子结构。这种多参考微扰理论的新进展,即IVO-SSMRPT,确保了即使在小参考空间的情况下,它也能够以合理的精度描述类自由基的结构。IVO-SSMRPT还能够预测最低单重态-三重态能隙的正确顺序。对氧分子的前三个电子态的研究也被用于评估我们的方法。我们的估计与现有的昂贵得多的基准最先进的从头算计算结果的一致性是可信的。IVO-SSMRPT方法为精确处理具有不同程度准简并性的类自由基体系提供了一条成本/精度比可控的有效途径。
