Fibril-Type Textile Electrodes Enabling Extremely High Areal Capacity through Pseudocapacitive Electroplating onto Chalcogenide Nanoparticle-Encapsulated Fibrils (Adv. Sci. 33/2022)
Energy Storage Devices
In article number 2203800, Yongmin Ko, Jinhan Cho and co-workers investigate fibril-type textile electrodes which exhibit extremely high areal capacity from chalcogenide nanoparticle assembly-driven pseudocapacitive electroplating process. Conductive and energy storage materials can be effectively introduced into 3D porous textiles by considering favorable interfacial interactions between each material. This approach plays a pivotal role in preparing high-performance energy storage devices.
Wiley_Advanced Science
Volume9, Issue33
November 24, 2022
2270209
Fibril-Type Textile Electrodes Enabling Extremely High Areal Capacity through Pseudocapacitive Electroplating onto Chalcogenide Nanoparticle-Encapsulated Fibrils (Adv. Sci. 33/2022)
Energy Storage Devices
In article number 2203800, Yongmin Ko, Jinhan Cho and co-workers investigate fibril-type textile electrodes which exhibit extremely high areal capacity from chalcogenide nanoparticle assembly-driven pseudocapacitive electroplating process. Conductive and energy storage materials can be effectively introduced into 3D porous textiles by considering favorable interfacial interactions between each material. This approach plays a pivotal role in preparing high-performance energy storage devices.
Fibril‐Type Textile Electrodes Enabling Extremely High Areal Capacity through Pseudocapacitive Electroplating onto Chalcogenide Nanoparticle‐Encapsulated Fibrils (Adv. Sci. 33/2022) - Chang - 2022 - Advanced Science - Wiley Online Library
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