Optical Transmittance Enhancement of Flexible Copper Film Electrodes with a Wetting Layer for Organic Solar Cells.
Guoqing ZhaoMyungkwan SongHee-Suk ChungSoo Min KimSang-Geul LeeJong-Seong BaeTae-Sung BaeDonghwan KimGun-Hwan LeeSeung Zeon HanHae-Seok LeeEun-Ae ChoiJungheum YunPublished in: ACS applied materials & interfaces (2017)
The development of highly efficient flexible transparent electrodes (FTEs) supported on polymer substrates is of great importance to the realization of portable and bendable photovoltaic devices. Highly conductive, low-cost Cu has attracted attention as a promising alternative for replacing expensive indium tin oxide (ITO) and Ag. However, highly efficient, Cu-based FTEs are currently unavailable because of the absence of an efficient means of attaining an atomically thin, completely continuous Cu film that simultaneously exhibits enhanced optical transmittance and electrical conductivity. Here, strong two-dimensional (2D) epitaxy of Cu on ZnO is reported by applying an atomically thin (around 1 nm) oxygen-doped Cu wetting layer. Analyses of transmission electron microscopy images and X-ray diffraction patterns, combined with first-principles density functional theory calculations, reveal that the reduction in the surface and interface free energies of the wetting layers with a trace amount (1-2 atom %) of oxygen are largely responsible for the two-dimensional epitaxial growth of the Cu on ZnO. The ultrathin 2D Cu layer, embedded between ZnO films, exhibits a highly desirable optical transmittance of over 85% in a wavelength range of 400-800 nm and a sheet resistance of 11 Ω sq-1. The validity of this innovative approach is verified with a Cu-based FTE that contributes to the light-to-electron conversion efficiency of a flexible organic solar cell that incorporates the transparent electrode (7.7%), which far surpasses that of a solar cell with conventional ITO (6.4%).
Keyphrases
- highly efficient
- density functional theory
- reduced graphene oxide
- metal organic framework
- solar cells
- room temperature
- aqueous solution
- quantum dots
- electron microscopy
- low cost
- high resolution
- single cell
- molecular dynamics
- photodynamic therapy
- cell therapy
- carbon nanotubes
- high speed
- gene expression
- heavy metals
- machine learning
- magnetic resonance imaging
- visible light
- magnetic resonance
- bone marrow
- ionic liquid
- optical coherence tomography
- computed tomography
- convolutional neural network
- electron transfer