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Hierarchical 3D Percolation Network of Ag-Au Core-Shell Nanowire-Hydrogel Composite for Efficient Biohybride Electrodes

Cited 11 time in Web of Science Cited 11 time in Scopus
Authors

Choi, Joonhwa; Min, Jinki; Kim, Dohyung; Kim, Jin; Kim, Jinsol; Yoon, Hyeokjun; Lee, Jinwoo; Jeong, Youngin; Kim, C-Yoon; Ko, Seung Hwan

Issue Date
2023-09
Publisher
American Chemical Society
Citation
ACS Nano, Vol.17 No.18, pp.17966-17978
Abstract
Metal nanomaterials are highly valued for their enhanced surface area and electrochemical properties, which are crucial for energy devices and bioelectronics. However, their practical applications are often limited by challenges, such as scalability and dimensional constraints. In this study, we developed a synthesis method for highly porous Ag-Au core-shell nanowire foam (AACNF) using a one-pot process based on a simultaneous nanowelding synthesis method. The unique characteristics of AACNF as metal-based electrodes show the lowest density among metal-based electrodes while demonstrating high electrical conductivity (99.33-753.04 S/m) and mechanical stability. The AACNF's excellent mass transport properties enable multiscale hierarchical incorporation with functional materials including polymeric precursors and living cells. The enhanced mechanical stability at the nanowelded junctions allows AACNF-hydrogel composites to exhibit large stretching (similar to 700%) and 10,000 times higher electrical conductivity than hydrogel-nanowire composites without the junction. Large particles in the 1-10 mu m scale, including fibroblast cells and exoelectrogenic microbes, are also successfully incorporated with AACNF. AACNF-based microbial fuel cells show high power density (similar to 330.1 W/m(3)) within the optimal density range. AACNF's distinctive ability to form a hierarchical structure with substances in various scales showcases its potential for advanced energy devices and biohybrid electrodes in the future.
ISSN
1936-0851
URI
https://hdl.handle.net/10371/205205
DOI
https://doi.org/10.1021/acsnano.3c04292
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  • College of Engineering
  • Department of Mechanical Engineering
Research Area Laser Assisted Patterning, Liquid Crystal Elastomer, Stretchable Electronics, 로보틱스, 스마트 제조, 열공학

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