Menezes Heloisa N S, Júnior Henrique C S, Ferreira Glaucio B
Departamento de Química Inorgânica, Instituto de Química, Universidade Federal Fluminense, Outeiro de S. João Batista s/n., Centro, Niterói, RJ, 24210-130, Brazil.
Programa de Pós-Graduação em Química, Instituto de Química, Universidade Federal do Rio Grande do Sul, Avenida Bento Gonçalves, 9500, Agronomia, Porto Alegre, RS, 90650-001, Brazil.
J Mol Model. 2024 Jul 8;30(8):258. doi: 10.1007/s00894-024-06052-6.
1,3-Dithiole-2-thione-4,5-dithiolate (dmit) ligands are known for their conductive and optical properties. Dmit compounds have been assessed for use in sensor devices, information storage, spintronics, and optical material applications. Associations with various metallic centers endow dmit complexes with magnetic, optical, conductive, and antioxidant properties. Optical doping can facilitate the fabrication of magnetic conductor materials from ground-state nonmagnetic cations. While most studied complexes involve transition-metal centers due to their diverse chemistry, compounds with representative elements are less explored in the literature. This study investigated the structural and electronic properties of bisdmit complexes with representative Bi(III), Sb(III), and Zn(II) cations. AIMD calculations revealed two new geometries for Bi(III) and Zn(II) complexes, diverging from the isolated geometry typically used in quantum chemical calculations. The coordination of acetonitrile molecules to the cationic centers of the complexes resulted in unstable structures, while the dimerization of the complexes was stable. SA-CASSCF/NEVPT2 calculations were applied to the structures of the isolated complexes and stable dimers, confirming the multireference character of the electronic structure of the three systems and the multiconfigurational character of the Bi(III) complex. The electronic spectra simulated by the STEOM-DLPNO-CCSD calculations accurately reproduced the experimental UV‒Vis spectra indicating the participation of the isolated Bi(III) dmit complex and its dimeric form in solution.
AIMD calculations of the dmit salts were conducted using the GFN2-xTB method with 60 explicit acetonitrile molecules as the solvent at 300 K for a total simulation time of 50.0 ps, with printing intervals of 0.5 fs. The final geometries were optimized employing the PBEh-3c compound method, incorporating implicit conductor-like polarizable continuum model (CPCM) solvation for acetonitrile. Local energy decomposition (LED) analysis at the DLPNO-CCSD(T)/Def2-TZVP level of theory was utilized to investigate the stability of the complex geometries identified by AIMD. The electronic structures of the complexes were assessed using the SA-CASSCF/NEVPT2/Def2-TZVP method to confirm the multiconfigurational and multireference nature of their electronic structures. Electronic spectra were analyzed using the STEOM-DLPNO-CCSD/Def2-TZVP method, with CPCM used to simulate an acetonitrile medium.
1,3 - 二硫杂环戊烯 - 2 - 硫酮 - 4,5 - 二硫醇盐(dmit)配体因其导电和光学性质而闻名。已对dmit化合物在传感器设备、信息存储、自旋电子学和光学材料应用方面的用途进行了评估。与各种金属中心的结合赋予dmit配合物磁性、光学、导电和抗氧化性能。光学掺杂有助于由基态非磁性阳离子制备磁性导体材料。虽然由于其多样的化学性质,大多数研究的配合物涉及过渡金属中心,但文献中对具有代表性元素的化合物的探索较少。本研究调查了具有代表性的Bi(III)、Sb(III)和Zn(II)阳离子的双dmit配合物的结构和电子性质。AIMD计算揭示了Bi(III)和Zn(II)配合物的两种新几何结构,与量子化学计算中通常使用的孤立几何结构不同。乙腈分子与配合物阳离子中心的配位导致结构不稳定,而配合物的二聚化是稳定的。SA - CASSCF/NEVPT2计算应用于孤立配合物和稳定二聚体的结构,证实了这三个体系电子结构的多参考特征以及Bi(III)配合物的多构型特征。通过STEOM - DLPNO - CCSD计算模拟的电子光谱准确再现了实验紫外 - 可见光谱,表明孤立的Bi(III) dmit配合物及其二聚体形式在溶液中的参与情况。
使用GFN2 - xTB方法对dmit盐进行AIMD计算,以60个明确的乙腈分子作为溶剂,在300 K下进行总模拟时间为50.0 ps的计算,打印间隔为0.5 fs。最终几何结构采用PBEh - 3c复合方法进行优化,并结合用于乙腈的隐式导体类极化连续介质模型(CPCM)溶剂化。在DLPNO - CCSD(T)/Def2 - TZVP理论水平上进行局部能量分解(LED)分析,以研究AIMD确定的配合物几何结构的稳定性。使用SA - CASSCF/NEVPT2/Def2 - TZVP方法评估配合物的电子结构,以确认其电子结构的多构型和多参考性质。使用STEOM - DLPNO - CCSD/Def2 - TZVP方法分析电子光谱,并用CPCM模拟乙腈介质。
