The PCPDTBT Family: Correlations between Chemical Structure, Polymorphism, and Device Performance

Schulz, Gisela L.; Fischer, Florian S. U.; Trefz, Daniel; Melnyk, Anton; Hamidi-Sakr, Amer; Brinkmann, Martin; Andrienko, Denis; Ludwigs, Sabine

doi:10.1021/acs.macromol.6b01698

Cited by 53 publications

(70 citation statements)

References 52 publications

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“…For comparison to C‐PCPDTBT, the thin film absorption spectra of Si‐PCPDTBT (M n = 11.0 kg mol ‐1 and PDI = 2.9) deposited from CHCl 3 and CB are shown in Figure b . While the overall shape of the spectra is similar to the carbon analogue, Si‐PCPDTBT shows regardless of solvent, a very pronounced aggregation shoulder at 760 nm . Our data indicate that the morphology (not shown) of Si‐PCPDTBT is much more dominated by aggregation in solution than in the case of C‐PCPDTBT.…”

Section: Third Generation Donor‐acceptor Copolymer: C‐pcpdtbtmentioning

confidence: 55%

“…c) AFM height image of C‐PCPDTBT thin film spin coated from CB/DIO. d) Bilayer solar cell device architecture, e) field‐effect transistor device structure, f) J‐V curves of the solar cells and g) FET hole mobilities of the two polymorphs . Reproduced and adapted with permission .…”

Section: Third Generation Donor‐acceptor Copolymer: C‐pcpdtbtmentioning

confidence: 99%

“…The charge transport properties of the two different polymorphs: dimer and long‐range π‐stacked, were investigated using field‐effect transistors consisting of a top gate, bottom‐contact architecture (see Figure e) . This device architecture was employed since the same polymer interface investigated in AFM is probed during transistor operation.…”

Section: Third Generation Donor‐acceptor Copolymer: C‐pcpdtbtmentioning

confidence: 99%

See 2 more Smart Citations

Controlled Crystallization of Conjugated Polymer Films from Solution and Solvent Vapor for Polymer Electronics

Schulz

Ludwigs

2016

Adv Funct Materials

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Over the years, solution‐processable conjugated oligomers and polymers have proven to be very promising for application in organic electronic devices. In addition to tuning the chemical structure of the materials, the role of morphology has been identified as a key parameter in determining device performance. Conjugated polymers are typically semicrystalline in nature consisting of both crystalline and amorphous domains giving rise to a wealth of superstructures. In comparison to classical non‐conjugated semicrystalline polymers, they bear the additional advantage of absorbing light. This makes UV‐vis absorption spectroscopy an excellent tool to monitor polymer aggregation and crystallization in‐situ both in solution and in films. With this feature article we point out the delicate interplay between solution processing and the obtained morphology in polythiophenes and low bandgap copolymers. Subtle changes in the preparation protocol lead to significant changes in textures and also give rise to polymorphism. Solvent vapor annealing and solution crystallization are highlighted as tools to control the nucleation and growth processes in semicrystalline polymer films. Structure‐function relationships between morphological, optical and electronic properties are demonstrated.

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Section: Third Generation Donor‐acceptor Copolymer: C‐pcpdtbtmentioning

confidence: 55%

Section: Third Generation Donor‐acceptor Copolymer: C‐pcpdtbtmentioning

confidence: 99%

Section: Third Generation Donor‐acceptor Copolymer: C‐pcpdtbtmentioning

confidence: 99%

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Controlled Crystallization of Conjugated Polymer Films from Solution and Solvent Vapor for Polymer Electronics

Schulz

Ludwigs

2016

Adv Funct Materials

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“…These typically involve the steps of simulating realistic morphologies by molecular dynamics, partitioning into conjugation segments, calculating molecular charge transfer rates for pairs of conjugation segments and simulating the charge dynamics by master equation or kinetic Monte Carlo methods 75,76 . These methods were first applied to molecular systems such as discotic liquid crystals 77 , but have since also been shown to provide realistic estimates of carrier mobilities in conjugated polymers, including P3HT 78 , PBTTT 79,80 or the D-A copolymer PCPDTBT 81 . For PBTTT it was shown that the fluctuations in the transfer integrals (that is, dynamic disorder) occur mostly on timescales of <100 fs, which are faster than the timescale for charge transfer.…”

Section: Charge Transport In Low-disorder Conjugated Polymersmentioning

confidence: 99%

Charge transport in high-mobility conjugated polymers and molecular semiconductors

et al. 2020

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Conjugated polymers and molecular semiconductors are emerging as a viable semiconductor technology in industries such as displays, electronics, renewable energy, sensing and healthcare. A key enabling factor has been significant scientific progress in improving their charge transport properties and carrier mobilities, which has been made possible by a better understanding of the molecular structure-property relationships and the underpinning charge transport physics. Here we aim to present a coherent review of how we understand charge transport in these high-mobility van der Waals bonded semiconductors. Specific questions of interest include estimates for intrinsic limits to the carrier mobilities that might ultimately be achievable; a discussion of the coupling between charge and structural dynamics; the importance of molecular conformations and mesoscale structural features; how the transport physics of conjugated polymers and small molecule semiconductors are related; and how the incorporation of counterions in doped films-as used, for example, in bioelectronics and thermoelectric devices-affects the electronic structure and charge transport properties.

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“…The structure of D‐A conjugated polymers is rather complex. Nanowires or nanofibers of several D‐A conjugated polymers had been reported . For example, Mullen et al prepared cyclopentadithiophene‐benzothiadiazole copolymer (CDT‐BTZ) nanowires by solvent vapor enhanced drop casting .…”

Section: Conjugated Polymer Single Crystals and Nanowiresmentioning

confidence: 99%

Conjugated polymer single crystals and nanowires

Cao

Zhao

Liang

et al. 2019

Polymer Crystallization

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Conjugated polymer single crystals and nanowires show advantages for the study of intrinsic charge transport in conjugated polymers and achieve high device performance. However, preparation of conjugated polymer single crystals and nanowires, especially donor‐acceptor (D‐A) conjugated polymers, is challenging. In this review, the structural features of conjugated polymers are first described. Then, the mechanism of conjugated polymer crystallization in terms of thermodynamic equilibrium state, nucleation, and growth is discussed. Single crystals of poly(alkylthiophene)s (P3ATs) and nanowires of both P3ATs and D‐A conjugated polymers are subsequently reviewed. Growth kinetics are a key issue in growing D‐A‐conjugated polymer crystals. Finally, the device performance based on conjugated polymer single crystals and nanowires is summarized.

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The PCPDTBT Family: Correlations between Chemical Structure, Polymorphism, and Device Performance

Cited by 53 publications

References 52 publications

Controlled Crystallization of Conjugated Polymer Films from Solution and Solvent Vapor for Polymer Electronics

Controlled Crystallization of Conjugated Polymer Films from Solution and Solvent Vapor for Polymer Electronics

Charge transport in high-mobility conjugated polymers and molecular semiconductors

Conjugated polymer single crystals and nanowires

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