超级电容器
电容
不透明度
材料科学
制作
透射率
卷到卷处理
分离器(采油)
光电子学
电极
纳米技术
3D打印
复合材料
光学
化学
物理
病理
物理化学
热力学
医学
替代医学
作者
Manoj Mayaji Ovhal,Neeraj Kumar,Haebeom Lee,Barkha Tyagi,Keum-Jin Ko,Shahd Boud,Jae-Wook Kang
标识
DOI:10.1016/j.xcrp.2021.100562
摘要
Roll-to-roll (R2R) fabrication of flexible and transparent all-solid-state supercapacitors (FT-ASSCs) is extremely challenging because of the classic trade-off between transparency and capacitance. In this work, we develop fully three-dimensional (3D)-printed, sandwich-type FT-ASSCs comprised of 3D line-patterned carbon black (CB)/Ag/CB electrodes on a transparent dialysis membrane (DM) separator. By tailoring the line pitch of the 3D electrodes, our FT-ASSC is able to achieve more than 80% optical transmittance and significantly higher areal capacitance than an opaque ASSC. More importantly, the performance of 3D-printed FT-ASSCs is unrestricted by the transparency-capacitance trade-off, and they exhibit a superior capacitive figure of merit value compared with state-of-the-art FT-ASSCs reported in the literature. Additionally, our FT-ASSCs demonstrate excellent cyclic stability and mechanical robustness because of the chemical and mechanical stability of the DM separator and effective encapsulation of polyurethane. The single-flow 3D printing technique introduced here can meet the requirements for industrial-scale R2R manufacturing of energy storage devices. • Transmittance of FT-ASSCs increases without sacrificing capacitance • FT-ASSCs achieve T 550 nm of 80.7% ± 0.9% and ~172% ± 3% higher C a than opaque ASSCs • Surface area and charge transfer are in line with the thickness of 3D electrodes • Roll-to-roll 3D-printed FT-ASSC modules show excellent flexibility and shape adaptivity Ovhal et al. demonstrate fabrication of high-performance flexible and transparent all-solid-state supercapacitors (FT-ASSCs) using a roll-to-roll 3D printing process. Because these devices use line-patterned composite electrodes, the newly designed FT-ASSCs exhibit an optical transmittance of more than 80% and a significantly higher areal capacitance than opaque ASSCs with a similar architecture.
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