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Faculty for Biology, Chemistry, and Earth Sciences

Macromolecular Chemistry I:

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Schmode, P.; Ohayon, D.; Reichstein, P.M.; Savva, A.; Inal, S.; Thelakkat, M.: High-Performance Organic Electrochemical Transistors Based on Conjugated Polyelectrolyte Copolymers, Chemistry of Materials, 31(14), 5286-95 (2019) -- DOI: 10.1021/acs.chemmater.9b01722
Abstract:
A new generation of polythiophene-based polyelectrolytes is reported to address fundamental issues in organic electrochemical transistors (OECTs). In such devices, the semiconductor must be able to transport and store ions and possess simultaneously a very high electronic mobility. For this, the ion-conducting 6-(thiophen-3-yl) hexane-1-sulfonate tetramethylammonium monomer (THS–TMA+) is copolymerized with the hole-conducting 3-hexylthiophene (3HT) to obtain copolymers, PTHS–TMA+-co-P3HT 1–3 with a gradient architecture. The copolymers having up to 50 mol % 3HT content are easily oxidizable and are crystalline. Consequently, for the copolymers, a higher stability in water is achieved, thus reducing the amount of cross-linker needed to stabilize the film. Furthermore, OECTs using copolymers with 75 and 50 mol % of PTHS–TMA+ content exhibit 2–3 orders of magnitude higher ON/OFF ratio and an extremely lower threshold voltage (−0.15 V) compared to PTHS–TMA+. Additionally, high volumetric capacitance (C* > 100 F/cm3) is achieved, indicating that the ion transport is not hampered by the hydrophobic 3HT up to 50 mol %, for which a very high OECT hole mobility of 0.017 cm2/(V s) is also achieved. Thus, the concept of copolymerization to combine both ionic and electronic charge transport in an organic mixed conductor offers an elegant approach to obtain high-performance OECT materials.
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