戒指(化学)
接受者
密度泛函理论
非共价相互作用
有机太阳能电池
分子轨道
噻吩
化学
带隙
平面度测试
共面性
材料科学
相互作用能
位阻效应
光化学
替代(逻辑)
含时密度泛函理论
电子受体
计算化学
化学物理
发色团
有机半导体
轨道能级差
衍生工具(金融)
光电子学
碳纳米管
分子工程
结晶学
聚合物太阳能电池
分子物理学
合理设计
自然键轨道
分子
作者
Zhao Liu,Lei Wang,Shubin Lei,Zheng Sun,Huanhuan Gao,Haiyang Song
标识
DOI:10.1021/acs.jpca.5c04350
摘要
Selenium (Se) substitution critically modulates the acceptor electronic structures and optoelectronic properties. This study systematically modifies the high-performance nonfused ring electron acceptor (NFREA) 2BTh-2F through π-bridge S-to-Se substitutions. Using density functional theory (DFT) and time-dependent DFT (TD-DFT), we designed nine novel acceptors (Z1-Z9) and characterized their electronic/optoelectronic properties. Complementary atoms in molecules (AIM) topological analysis and reduced density gradient (RDG) analysis reveal enhanced Se···O noncovalent interactions (NCIs), though molecular planarity remains governed by steric constraints from three-dimensional (3D) side chains. Crucially, Se substitution optimizes the electrostatic potential (ESP) distribution, frontier molecular orbital (FMO) energy levels, and excited-state properties. Z5, a symmetrical Se-substituted derivative of the outer thiophene on the π-bridge, established itself as the most promising NFREA candidate due to its minimum band gap, maximum open-circuit voltage and fill factor, and minimum energy loss. These findings underscore rational substitution strategies for NFREA design and provide critical guidelines for the development of high-performance organic solar cells.
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