期刊
ADVANCED MATERIALS
卷 -, 期 -, 页码 -出版社
WILEY-V C H VERLAG GMBH
DOI: 10.1002/adma.202308631
关键词
conjugated polyelectrolytes; cycling stability; high-rate capability; pseudocapacitors
Films of anionic CPE-K drops cast from water can be used as stable solid-state pseudocapacitive electrodes in aqueous electrolytes. By increasing the electrolyte concentration, initially water soluble ionic-organic materials can be applied in batteries, organic electrochemical transistors, and electrochemical sensors.
A subclass of organic semiconductors known as conjugated polyelectrolytes (CPEs) is characterized by a conjugated backbone with ionic pendant groups. The water solubility of CPEs typically hinders applications of thin films in aqueous media. Herein, it is reported that films of an anionic CPE, namely CPE-K, drop cast from water produces single-component solid-state pseudocapacitive electrodes that are insoluble in aqueous electrolyte. That X-ray diffraction experiments reveal a more structurally ordered film, relative to the as-obtained powder from chemical synthesis, and dynamic light scattering measurements show an increase in aggregate particle size with increasing [KCl] indicate that CPE-K films are insoluble because of tight interchain contacts and electrostatic screening by the electrolyte. CPE-K film electrodes can maintain 85% of their original capacitance (84 F g-1) at 500 A g-1 and exhibit excellent cycling stability, where a capacitance retention of 93% after 100 000 cycles at a current density of 35 A g-1. These findings demonstrate that it is possible to use initially water soluble ionic-organic materials in aqueous electrolytes, by increasing the electrolyte concentration. This strategy can be applied to the application of conjugated polyelectrolytes in batteries, organic electrochemical transistors, and electrochemical sensors, where fast electron and ion transport are required. Slow evaporation from a pure water solution provides high charging rate pseudocapacitive conjugated polyelectrolyte films that are stable in aqueous electrolytes. Key to stability is increased crystallinity and a high electrolyte concentration for decreasing interchain electrostatic repulsion. This strategy may be applied for integrating organic mixed ionic electronic conductors in applications such as batteries, organic electrochemical transistors, or electrochemical sensors.image
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