Flexible large-area monolithic organic solar cells suffer from electrical loss during up-scaling due to the limited conductivity of transparent electrodes. In this work, highly conductive silver grid fingers are integrated onto a roll-to-roll gravure-printed silver nanowire electrode via roll-to-roll screen printing, significantly reducing the composite sheet resistance from 15 to 1.5 Ω sq−1. A numerical model is established to optimize grid width and spacing, achieving an equivalent sheet resistance of 1 ~ 2 Ω sq−1 for higher-resistance electrodes. A self-masking strategy is developed to prevent shunting caused by uneven grid surfaces. As a result, monolithic flexible organic solar cells with areas of 4 and 16 cm² achieve power conversion efficiencies of 15.20% and 14.24%, respectively, demonstrating minimal efficiency loss with increased area. Additionally, the devices exhibit excellent mechanical flexibility and shelf stability, enabled by a robust photoresist passivation layer. Han et al. report a highly conductive composite electrode with low equivalent sheet resistance of 1.5 Ω sq-1. A self-masking method is developed to prevent shunting caused by uneven grid surfaces, enabling flexible organic solar cells with efficiencies of 15.20% (4 cm2 devices) and 14.24% (16 cm2 devices).
Han et al. (Thu,) studied this question.