A pseudo-capacitive chalcogenide-based electrode with dense 1-dimensional nanoarrays for enhanced energy density in asymmetric supercapacitors
Young-Woo Lee, Byung-Sung Kima, Jong Hong, Juwon Lee, Sangyeon Pak,, Hyeon-Sik Jang, Dongmok Whang, SeungNam Cha, Jung Inn Sohn, and Jong Min Kim

TL;DR
This paper presents a novel dense nanoarray CuS nanowire electrode on Cu mesh, significantly enhancing energy density and cyclability in asymmetric supercapacitors through a simple fabrication process.
Contribution
The study introduces a new method to grow dense CuS nanowire arrays directly on Cu mesh, improving supercapacitor performance with binder-free electrodes.
Findings
Achieved high areal capacitance of 378.0 mF/cm2
Demonstrated 90.2% retention over 2000 cycles
Attained volumetric energy density of 1.11 mWh/cm3
Abstract
To achieve the further development of supercapacitors (SCs), which have intensively received attention as a next-generation energy storage system, the rational design of active electrode materials with electrochemically more favorable structure is one of the most important factors to improve the SC performance with high specific energy and power density. We propose and successfully grow copper sulfide (CuS) nanowires (NWs) as a chalcogenide-based electrode material directly on a Cu mesh current collector using the combination of a facile liquid-solid chemical oxidation process and an anion exchange reaction. We found that the as-prepared CuS NWs have well-arrayed structures with nanosized crystal grains, a high aspect ratio and density, as well as a good mechanical and electrical contact to the Cu mesh. The obtained CuS NW based electrodes, with additional binder- and conductive…
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Taxonomy
TopicsSupercapacitor Materials and Fabrication · Advanced battery technologies research · Electrocatalysts for Energy Conversion
