Backbone Tuning Enhances the Solution Aggregation to Refine Fibrillization Network Morphology for Efficient All-Chlorinated Polymer Donor

Pu，Mingrui1; Lai，Xue1; Li，Yan1; Zhu，Yulin1; Wei，Zixiang2; Zhu，Yiwu1; Chen，Hui1; Tian，Leilei2; He，Feng1,3

2023

10.1021/acsmaterialslett.3c00566

ACS Materials Letters   影响因子和分区

2639-4979

An ideal nanoscale interpenetrating network morphology that is formed spontaneously upon a prepared active layer film is the key to efficient exciton dissociation and charge transport. Here, a new strategy is described for optimization of morphology by enhancing polymer solution aggregation ability to effectively improve device performance. Polymers PBDQx-Cl, PBDQx-TCl, and PBDQx-2TCl were designed and synthesized systematically by tuning the polymer backbones. Structural manipulation has been found to have a profound effect on the regulation of electronic structure and solution aggregation behavior. Compared with PBDQx-Cl and PBDQx-TCl, PBDQx-2TCl exhibits enhanced solution aggregation ability and contributes to a fibrous phase separation in primitive pure film morphology. After blending with BTP-eC9, evolution of a nanoscale fibrillization interpenetrating network morphology is gradually demonstrated, in which the phase separation and microstructure form are collectively refined, which can provide more interface regions and charge transport channels. The resulting PBDQx-2TCl:BTP-eC9 micromorphologically meets the requirements for efficient exciton splitting, charge transfer, and decreased recombination loss. Thus, among the three polymers, the device based on PBDQx-2TCl:BTP-eC9 shows the highest PCE of 16.17% with superior J of 26.49 mA cm and FF of 74.28%. These results demonstrate that the well-refined fibrillar network morphology can be achieved by adjusting the aggregation ability of a polymer solution. This in turn promotes a deeper understanding of the relationships between micromorphology and solution aggregation behavior.

SCI ; EI

英语

第一 ; 通讯

National Natural Science Foundation of China["22225504","51973089","21975115"] ; Shenzhen Fundamental Research Program["JCYJ20200109140801751","JCYJ20210324120010028"] ; Shenzhen Science and Technology Innovation Commission[KQTD20170810111314625] ; Guangdong Provincial Key Laboratory of Catalysis[2020B121201002]

Materials Science

Materials Science, Multidisciplinary

WOS:001041650200001

AMER CHEMICAL SOC

20233414615471

Blending ; Electronic structure ; Excitons ; Morphology ; Nanotechnology ; Phase separation ; Tuning

Thermodynamics:641.1 ; Nanotechnology:761 ; Chemical Reactions:802.2 ; Chemical Operations:802.3 ; Physical Properties of Gases, Liquids and Solids:931.2 ; Materials Science:951

2-s2.0-85168480915

Scopus

1.Shenzhen Grubbs Institute and Department of Chemistry,Southern University of Science and Technology,Shenzhen,518055,China
2.Department of Materials Science and Engineering,Southern University of Science and Technology,Shenzhen,Guangdong,518055,China
3.Guangdong Provincial Key Laboratory of Catalysis,Southern University of Science and Technology,Shenzhen,518055,China

Pu，Mingrui,Lai，Xue,Li，Yan,et al. Backbone Tuning Enhances the Solution Aggregation to Refine Fibrillization Network Morphology for Efficient All-Chlorinated Polymer Donor[J]. ACS Materials Letters,2023,5(9):2369-2376.

Pu，Mingrui.,Lai，Xue.,Li，Yan.,Zhu，Yulin.,Wei，Zixiang.,...&He，Feng.(2023).Backbone Tuning Enhances the Solution Aggregation to Refine Fibrillization Network Morphology for Efficient All-Chlorinated Polymer Donor.ACS Materials Letters,5(9),2369-2376.

Pu，Mingrui,et al."Backbone Tuning Enhances the Solution Aggregation to Refine Fibrillization Network Morphology for Efficient All-Chlorinated Polymer Donor".ACS Materials Letters 5.9(2023):2369-2376.