各向同性
极化(电化学)
密度泛函理论
极化率
各向异性
半导体
有机半导体
分子物理学
极化连续介质模型
化学物理
材料科学
溶剂化
化学
计算物理学
物理
计算化学
光电子学
分子
量子力学
物理化学
作者
Qianqian Jin,Tao Xu,Changwei Wang,Shiwei Yin
标识
DOI:10.1021/acs.jpca.5c03435
摘要
Accurate modeling of charge carrier energetics in organic semiconductors is essential for understanding and optimizing their performance in optoelectronic devices. In this work, we employ the absolutely localized molecular orbital (ALMO) method within density functional theory (DFT) as a quantum mechanical benchmark to evaluate the performance of isotropic (ISO) and anisotropic (ANISO) polarization models implemented in the AMOEBA polarizable force field (PFF). By analyzing a set of representative p-type and n-type organic semiconductors in both bulk-like (center-site) and surface-like (edge-site) cluster configurations, we assess the ability of each model to reproduce ALMO-based apparent polarization energies. Our results show that both ISO and ANISO models yield comparable accuracy in centrosymmetric (bulk-like) environments due to the suppression of anisotropic polarization effects. However, the ANISO model significantly outperforms the ISO model in asymmetric configurations, such as at molecular surfaces or heterojunction interfaces, where direction-dependent polarization becomes non-negligible. ALMO-based energy decomposition analysis (ALMO-EDA) reveals that polarization interactions are the dominant contribution to the transport gap in the condensed phase. This finding provides a simplified theoretical framework for estimating the transport gap by considering only polarization effects. Overall, this study establishes the reliability of the ALMO method as a reference for evaluating polarization models and highlights the importance of incorporating anisotropic polarizability in force fields for accurate modeling of charge localization and transport phenomena in organic materials.
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