侧链交叉对平面吲哚二噻吩共聚物应变和电荷迁移率的影响

IF 4.7 Q1 POLYMER SCIENCE ACS polymers Au Pub Date : 2022-09-29 DOI:10.1021/acspolymersau.2c00034
Parker J. W. Sommerville, Alex H. Balzer, Garrett Lecroy, Lorenzo Guio, Yunfei Wang, Jonathan W. Onorato, Nadzeya A. Kukhta, Xiaodan Gu, Alberto Salleo, Natalie Stingelin and Christine K. Luscombe*, 
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引用次数: 4

摘要

茚并二噻吩(IDT)共聚物是一类共轭聚合物,具有有限的长程有序性和高空穴迁移率,这使它们有望用于可变形电子器件。它们高空穴迁移率的关键是主链内的共面单体重复单元。聚(茚并二噻吩-苯并噻二唑)(PIDTC16-BT)和聚(茚二噻吩-噻焦二酮)(PIDTCP16-TPDC1)是两种具有平面主链的IDT共聚物,但它们在低分子量下是脆性的,并且具有不合适的高弹性模量。用异丁烷(C20)侧链取代IDT单体的十六烷(C16)侧链以产生新的含BT的IDT共聚物PIDTC20-BT。用TPD单体上的甲基(C1)侧链取代辛基(C8)和6-乙基十一烷(C13B)得到两种新的含TPD的IDT共聚物,分别命名为PIDTC16-TPDC8和PIDTC16-TPPDC13B。PIDTC16-TPDC8和PIDTC16-TPPDC13B都是相对良好的可变形性,具有低的屈服应变,并且显示出显著降低的弹性模量。这些机械性能表现出来是因为从TPD单体延伸的延长侧链抑制了精确的分子间有序。在PIDTC16-BT中,PIDTC20-BT和PIDTC16-TPDC1侧链排序可能发生,因为侧链仅存在于IDT亚基上,但这会导致脆性薄膜。相反,PIDTC16-TPDC8和PIDTC16-TPPDC13B具有无序的侧链,这似乎导致低空穴迁移率。这些结果表明,通过共聚单体侧链延伸破坏IDT共聚物中的叉指状会导致具有较低弹性模量的更具延展性的薄膜,但由于相应薄膜中的局部顺序改变,空穴迁移率降低。因此,我们的工作强调了可变形电子材料的分子填充结构之间的权衡,并为设计可拉伸电子产品的新型共轭聚合物提供了指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Influence of Side Chain Interdigitation on Strain and Charge Mobility of Planar Indacenodithiophene Copolymers

Indacenodithiophene (IDT) copolymers are a class of conjugated polymers that have limited long-range order and high hole mobilities, which makes them promising candidates for use in deformable electronic devices. Key to their high hole mobilities is the coplanar monomer repeat units within the backbone. Poly(indacenodithiophene-benzothiadiazole) (PIDTC16-BT) and poly(indacenodithiophene-thiapyrollodione) (PIDTC16-TPDC1) are two IDT copolymers with planar backbones, but they are brittle at low molecular weight and have unsuitably high elastic moduli. Substitution of the hexadecane (C16) side chains of the IDT monomer with isocane (C20) side chains was performed to generate a new BT-containing IDT copolymer: PIDTC20-BT. Substitution of the methyl (C1) side chain on the TPD monomer for an octyl (C8) and 6-ethylundecane (C13B) afford two new TPD-containing IDT copolymers named PIDTC16-TPDC8 and PIDTC16-TPDC13B, respectively. Both PIDTC16-TPDC8 and PIDTC16-TPDC13B are relatively well deformable, have a low yield strain, and display significantly reduced elastic moduli. These mechanical properties manifest themselves because the lengthened side chains extending from the TPD-monomer inhibit precise intermolecular ordering. In PIDTC16-BT, PIDTC20-BT and PIDTC16-TPDC1 side chain ordering can occur because the side chains are only present on the IDT subunit, but this results in brittle thin films. In contrast, PIDTC16-TPDC8 and PIDTC16-TPDC13B have disordered side chains, which seems to lead to low hole mobilities. These results suggest that disrupting the interdigitation in IDT copolymers through comonomer side chain extension leads to more ductile thin films with lower elastic moduli, but decreased hole mobility because of altered local order in the respective thin films. Our work, thus, highlights the trade-off between molecular packing structure for deformable electronic materials and provides guidance for designing new conjugated polymers for stretchable electronics.

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