离域电子
极化子
材料科学
声子
电子迁移率
电荷(物理)
分子内力
载流子
分子间力
化学物理
凝聚态物理
散射
光电子学
分子物理学
纳米技术
物理
电子
分子
量子力学
作者
Zhigang Shuai,Linjun Wang,Qikai Li
标识
DOI:10.1002/adma.201003503
摘要
Abstract The carrier mobility for carbon electronic materials is an important parameter for optoelectronics. We report here some recently developed theoretical tools to predict the mobility without any free parameters. Carrier scatterings with phonons and traps are the key factors in evaluating the mobility. We consider three major scattering regimes: i) where the molecular internal vibration severely induces charge self‐trapping and, thus, the hopping mechanism dominates; ii) where both intermolecular and intramolecular scatterings come to play roles, so the Holstein‐Peierls polaron model is applied; and, iii) where charge is well delocalized with coherence length comparable with acoustic phonon wavelength, so that a deformation potential approach is more appropriate. We develop computational methods at the first‐principles level for the three different cases that have extensive potential application in rationalizing material design.
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