Omar O'Mari, Moon Young Yang, William Goddard, Valentine I Vullev
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引用次数: 0
摘要
分子驻极体对于电子材料和器件非常重要,其构象波动会对其大极和固有特性产生强烈影响。在此,我们采用分子动力学(MD)模拟和可极化电荷平衡(PQEq)方法来研究由蒽酰胺(Aa)残基组成的分子驻极体的持续长度(LP)。PQEq-MD 消除了关于 Aa 大分子的公认静态概念,LP 代表最短的 Aa 刚性片段。单一 LP 值的经典模型无法描述这些低聚物。为同一种大分子引入多个 LP 值可遵循观察到的趋势,并将中间部分增强的刚度与末端区域降低的刚度区分开来。此外,LP 值明显取决于溶剂的极性。Aa 低聚物在非极性溶剂中保持扩展构象,LP 超过 4 nm,而在极性介质中,构象波动的增加使 LP 降至约 2 nm。这些特性为 Aa 共轭物在有机电子学和能源工程中的电荷转移系统中的应用提供了重要指导。
As important as molecular electrets are for electronic materials and devices, conformational fluctuations strongly impact their macrodipoles and intrinsic properties. Herein, we employ molecular dynamics (MD) simulations with the polarizable charge equilibrium (PQEq) method to investigate the persistence length (LP) of molecular electrets composed of anthranilamide (Aa) residues. The PQEq-MD dissipates the accepted static notions about Aa macromolecules, and LP represents the shortest Aa rigid segments. The classical model with a single LP value does not describe these oligomers. Introducing multiple LP values for the same macromolecule follows the observed trends and discerns the enhanced rigidity in their middle sections from the reduced stiffness at their terminal regions. Furthermore, LP distinctly depends on solvent polarity. The Aa oligomers maintain extended conformations in nonpolar solvents with LP exceeding 4 nm, while in polar media, increased conformational fluctuations reduce LP to about 2 nm. These characteristics set key guidelines about the utility of Aa conjugates for charge-transfer systems within organic electronics and energy engineering.
期刊介绍:
An essential criterion for acceptance of research articles in the journal is that they provide new physical insight. Please refer to the New Physical Insights virtual issue on what constitutes new physical insight. Manuscripts that are essentially reporting data or applications of data are, in general, not suitable for publication in JPC B.