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Detail
Journal Article
Highly conductive and transparent metal microfiber networks as front electrodes of flexible thin-film photovoltaics
- Authors
- Dae-Hyung Cho, Woo-Jung Lee, Tae-Ha Hwang, Jungwoo Huh, Sam S. Yoon, YongDuck Chung
- Issue Date
- 2024-05
- Citation
- Journal of Power Sources, v.603, pp.1-7
- ISSN
- 0378-7753
- Publisher
- Elsevier BV
- Language
- English
- Type
- Journal Article
- Abstract
- Simultaneously enhancing the optical transmittance and electrical conductivity of transparent conductors (TCs) applicable in various optoelectronic devices is a long-standing challenge. Herein, we present an innovative approach for fabricating electroplated Ni and Cu microfiber networks (NiMF and CuMF) as highly conductive TCs to realize high efficiency and desired aesthetics in thin-film solar cells and modules. The metal microfibers (MFs) are fabricated using electrospun polyacrylonitrile nanofibers as the template. The large cross-sectional aspect ratio of the metal MF networks remarkably and concurrently improves their electrical conductivity and optical transmittance. Between the NiMF and CuMF TCs, the CuMF sample exhibits a superior figure of merit owing to its exceptionally low electrical resistivity. The metal MF TC is a promising alternative to conventional patterned grids used in flexible Cu(In,Ga)Se2 thin-film solar cells, because it effectively reduces the series resistance, which is advantageous for large-area cells. The CuMF can be successfully employed as a ribbon to maintain the solar cell performance in centimeter-scale cells connected in series. The outstanding performance of the metal MF TCs indicates their potential to eliminate complicated monolithic integration processes or front grids and ribbons in flexible thin-film solar cells and modules.
- KSP Keywords
- Cross-sectional, Electrical Conductivity, Electroplated Ni, Figure of Merit(FoM), Innovative approach, Monolithic Integration, Optoelectronic devices, Polyacrylonitrile nanofiber, Solar cell performance, aspect ratio, centimeter-scale
This work is distributed under the term of Creative Commons License (CCL)
(CC BY NC)
(CC BY NC)
