Effect of different π bridges on electro-optic properties of D-A-D type conjugated polymers based on nitro-substituted triphenylamine derivatives

IF 4.5 2区化学 Q2 POLYMER SCIENCE Polymer Pub Date : 2025-02-14 Epub Date: 2025-01-13 DOI:10.1016/j.polymer.2025.128041

Pengjie Chao , Yuqing Liao , Dongling Shen , Daize Mo , Lanqing Li , Donghua Fan

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Abstract

We designed and synthesized two monomers, TTTPA and TETPA, by inserting the EDOT and thiophene unit as π-bridges between thiophene unit and nitro-substituted triphenylamine (TPA) through Stille coupling reaction, and the corresponding polymers PTTTPA and PTETPA were also prepared by electrochemical polymerization. Both TTTPA and TETPA displayed the red-shifted absorption spectra and lower onset oxidation potential, in particular, TETPA possessed a much lower initial oxidation potential of 0.68 V than its counterpart TTPA (1.00 V) without π-bridges. In addition, PTTTPA possessed the reversible and stable color change from yellow to gray between the neutral and oxidized state with a higher optical contrast of 27.1 %, and exhibited a higher coloration efficiency of 134.43 cm² C⁻¹ when compared with PTTPA and PTETPA. These results demonstrated that the reasonable introduction of π-bridges could optimize the electrochromic performance of TPA-based polymer.

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不同π桥对基于硝基取代三苯胺衍生物的D-A-D型共轭聚合物电光性能的影响

通过Stille偶联反应，将EDOT和噻吩单元作为噻吩单元与硝基取代三苯胺（TPA）之间的π桥，设计合成了TTTPA和TETPA两个单体，并通过电化学聚合制备了相应的聚合物PTTTPA和PTETPA。TTTPA和TETPA均表现出红移吸收光谱和较低的起氧化电位，其中TETPA的起氧化电位为0.68 V，远低于没有π桥的TTPA （1.00 V）。此外，与PTTPA和PTETPA相比，PTTTPA在中性和氧化态之间具有从黄色到灰色的可逆稳定的变色特性，光学对比度高达27.1%，显色效率高达134.43 cm2 C-1。结果表明，合理引入π桥可以优化tpa基聚合物的电致变色性能。

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来源期刊

Polymer 化学-高分子科学

CiteScore

7.90

自引率

8.70%

发文量

959

审稿时长

32 days

期刊介绍： Polymer is an interdisciplinary journal dedicated to publishing innovative and significant advances in Polymer Physics, Chemistry and Technology. We welcome submissions on polymer hybrids, nanocomposites, characterisation and self-assembly. Polymer also publishes work on the technological application of polymers in energy and optoelectronics. The main scope is covered but not limited to the following core areas: Polymer Materials Nanocomposites and hybrid nanomaterials Polymer blends, films, fibres, networks and porous materials Physical Characterization Characterisation, modelling and simulation* of molecular and materials properties in bulk, solution, and thin films Polymer Engineering Advanced multiscale processing methods Polymer Synthesis, Modification and Self-assembly Including designer polymer architectures, mechanisms and kinetics, and supramolecular polymerization Technological Applications Polymers for energy generation and storage Polymer membranes for separation technology Polymers for opto- and microelectronics.