中文摘要：

近年来,有机场效应晶体管（OFETs）由于在柔性器件和可穿戴电子学中的潜在应用受到了学术界和工业界的普遍关注,尤其是以聚合物半导体材料构筑的晶体管性能得到了快速的发展.如何设计合成用于OFETs的高性能聚合物半导体材料,一直是我们的追求目标.然而,分子结构对迁移率的影响仍缺少系统的比较.本文综述了近年来国内外新型聚合物材料的最新进展.我们按照材料的种类以及载流子的传输类型进行了分类,对高性能聚合物材料的发展过程、材料的设计思路以及相应的FETs性能进行了系统地归纳总结.通过研究分子及分子聚集态结构与器件性能之间的关系,希望为以后设计合成新型的高性能的聚合物材料提供有益的借鉴和指导.

英文摘要：

In recent years, much attention has been paid to organic field-effect transistors（OFETs） due to their potential applications in flexible and wearable electronic devices. Especially for OFETs based on donor-acceptor（D-A） conjugated polymers, significant progress has been made. It is crucial to design and synthesize novel high-mobility polymers, the key components of OFETs. In this review, the recent progress of these novel polymeric materials is summarized to show the systematic effect of molecular structure on the mobility. The development, design and corresponding OFET performance are systematically summarized according to the different types of the polymers. These polymers are introduced based on the types of conventional acceptors, which include diketopyrrolopyrrole（DPP）, isoindigo（IID）, benzodifurandione-based oligo（p-phenylene vinylene）（BDOPV）, naphthalenediimide（NDI） and other novel moieties. These acceptors have been proven to be promising building blocks for high-mobility polymers due to their planar backbones, electron-deficient property, and facile chemical modifications. Based on these acceptors, p-type, ambipolar or n-type polymers can be achieved by using different donors or by introducing electron withdrawing groups onto the acceptor unit. Generally, DPP and IID based polymers are p-type or ambipolar materials. In contrast, n-type transport characteristics are observed in most of the polymers based on BDOPV and NDI. To date, a high hole mobility of up to 17.8 cm~2 V~（–1） s~（–1） has been achieved by a DPP-based polymer, while the reported highest electron mobility is of 8.5 cm~2 V~（–1） s~（–1） in a NDI-based polymer. Here, we have summarized some key points for high-performance polymers by investigating the relationship among molecular structure, aggregation type and device performance. In detail, high-mobility polymers generally show some features including fine-tuned highest occupied molecular orbital（HOMO） and lowest unoccupied molecular orbit