Abstract
We investigated the deposition rate effect on the optical, electrical, and morphological characteristics of thermally evaporated WO3−x/Ag/WO3−x (WAW) multilayer electrodes. By controlling the deposition rate of the WO3−x and Ag layers, we can control the interface structure between WO3−x and Ag and improve both the optical and electrical properties of the thermally evaporated WAW multilayer electrodes. At the optimized deposition rate of WO3−x (2.5 Å/sec) and Ag (10 Å/sec), the symmetric WAW multilayer exhibited a high optical transmittance of 92.16% at a 550 nm wavelength and low sheet resistance of 3.78 Ω/square. During repeated bending, rolling, and twisting, there was no resistance change indicating the superior flexibility of WAW multilayer electrodes. As a promising application of the WAW multilayer electrodes, we suggested the transparent and flexible thin film heaters (TFHs) to substitute the high cost indium tin oxide-based TFHs. In comparison to the ITO-based TFHs, the WAW based TFHs showed higher convective heat transfer property and higher saturation temperatures are achieved at lower input voltages due to lower sheet resistance. This indicates that the WAW multilayer is suitable as the electrode for high performance transparent and flexible TFHs.
Highlights
We investigated the deposition rate effect on the optical, electrical, and morphological characteristics of thermally evaporated WO3−x/Ag/WO3−x (WAW) multilayer electrodes
We investigated the effect of deposition rate on the electrical, optical and morphological properties of WO3−x/Ag/WO3−x (WAW) multilayer deposited on a colorless polyimide (CPI) substrate during the thermal evaporation process
We investigated the feasibility of thermally evaporated WAW multilayer electrode for application as flexible transparent conducting electrodes (TCEs) without indium for high-performance flexible thin film heaters (TFHs) and can be used as TCE for the next-generation optoelectronics and photovoltaics
Summary
We investigated the deposition rate effect on the optical, electrical, and morphological characteristics of thermally evaporated WO3−x/Ag/WO3−x (WAW) multilayer electrodes. As a promising application of the WAW multilayer electrodes, we suggested the transparent and flexible thin film heaters (TFHs) to substitute the high cost indium tin oxide-based TFHs. In comparison to the ITO-based TFHs, the WAW based TFHs showed higher convective heat transfer property and higher saturation temperatures are achieved at lower input voltages due to lower sheet resistance. The effect of the deposition rate on interface morphology, optical and electrical properties of the thermally evaporated OMO multilayer are rarely investigated compared to the effect of film thickness. We investigated the effect of deposition rate on the electrical, optical and morphological properties of WO3−x/Ag/WO3−x (WAW) multilayer deposited on a colorless polyimide (CPI) substrate during the thermal evaporation process. We investigated the correlation between performances of TFHs and electrical properties of the WAW multilayer electrodes to show the importance of thermally evaporated WAW electrode
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