Nanoscopic management of molecular packing and orientation of small molecules by a combination of linear and branched alkyl side chains
- Nanoscopic management of molecular packing and orientation of small molecules by a combination of linear and branched alkyl side chains
- 정민우; 윤영운; 박재훈; 차원석; 김아정; 강진백; Sanjeev Gautam; 서동균; 조정호; 김현정; 최종용; 채근화; 곽경원; 손해정; 고민재; 김홍곤; 이도권; 김진영; 최동훈; 김봉수
- organic semiconductors; conjugated small molecules; molecular self-assembly; molecular orientation; hole mobility; power conversion efficiency; organic field-effect transistors; organic photovoltaic cells
- Issue Date
- ACS Nano
- VOL 8, NO 6, 5988-6003
- We synthesized a series of acceptor–donor–acceptor-type small molecules (SIDPP-EE, SIDPP-EO, SIDPP-OE, and SIDPP-OO) consisting of a dithienosilole (SI) electron-donating moiety and two diketopyrrolopyrrole (DPP) electron-withdrawing moieties each bearing linear n-octyl (O) and/or branched 2-ethylhexyl (E) alkyl side chains. X-ray diffraction patterns revealed that SIDPP-EE and SIDPP-EO films were highly crystalline with pronounced edge-on orientation, whereas SIDPP-OE and SIDPP-OO films were less crystalline with a radial distribution of molecular orientations. Near-edge X-ray absorption fine structure spectroscopy disclosed an edge-on orientation with a molecular backbone tilt angle of ∼22° for both SIDPP-EE and SIDPP-EO. Our analysis of the molecular packing and orientation indicated that the shorter 2-ethylhexyl groups on the SI core promote tight π–π stacking of the molecular backbone, whereas n-octyl groups on the SI core hinder close π–π stacking to some degree. Conversely, the longer linear n-octyl groups on the DPP arms facilitate close intermolecular packing via octyl–octyl interdigitation. Quantum mechanics/molecular mechanics molecular dynamics simulations determined the optimal three-dimensional positions of the flexible alkyl side chains of the SI and DPP units, which elucidates the structural cause of the molecular packing and orientation explicitly. The alkyl-chain-dependent molecular stacking significantly affected the electrical properties of the molecular films. The edge-on oriented molecules showed high hole mobilities in organic field-effect transistors, while the radially oriented molecules exhibited high photovoltaic properties in organic photovoltaic cells. These results demonstrate that appropriate positioning of alkyl side chains can modulate crystallinity and molecular orientation in SIDPP films, which ultimately have a profound impact on carrier transpor
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