化学
离域电子
有机半导体
分子轨道
纳米技术
半导体
轨道能级差
分子固体
分子
化学物理
光电子学
材料科学
有机化学
作者
Zachary B. Henson,Kläus Müllen,Guillermo C. Bazan
出处
期刊:Nature Chemistry
[Springer Nature]
日期:2012-08-22
卷期号:4 (9): 699-704
被引量:517
摘要
Organic semiconducting materials based on polymers and molecular systems containing an electronically delocalized structure are the basis of emerging optoelectronic technologies such as plastic solar cells and flexible transistors. For isolated molecules, guidelines exist that rely on the molecular formula to tailor the frontier (highest occupied or lowest unoccupied) molecular orbital energy levels and optical absorption profiles. Much less control can be achieved over relevant properties, however, as one makes the transition to the ensemble behaviour characteristic of the solid state. Polymeric materials are also challenging owing to the statistical description of the average number of repeat units. Here we draw attention to the limitations of molecular formulae as predictive tools for achieving properties relevant to device performances. Illustrative examples highlight the relevance of organization across multiple length scales, and how device performances--although relevant for practical applications--poorly reflect the success of molecular design.
科研通智能强力驱动
Strongly Powered by AbleSci AI