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Harnessing plasmon-exciton energy exchange for flexible organic solar cells with efficiency of 19.5%

Jingde Chen, Hao Ren, Feng‐Ming Xie, Jialiang Zhang, Haoze Li, Abdul Sameeu Ibupoto, Y.X. Zhang, Yan-Qing Li, Jianxin Tang

2025Nature Communications15 citationsDOIOpen Access PDF

Abstract

The plasmonic effects have unlocked remarkable advancements in modern optoelectronics, enabling enhanced light-matter interactions for applications ranging from sensing to photovoltaics. However, the nonradiative damping of plasmonic effects causes parasitic absorption which limits the light-utilization efficiency of optoelectronics, particularly for photovoltaic cells. Herein, we propose a plasmon energy recycling scheme consisting of green fluorophore (BCzBN) and nickel oxide to compensate for the plasmon energy loss. The plasmons trapped in silver nanowire (AgNW) electrodes are coupled to green emission through plasmon-exciton energy exchange. Backward electron and energy transfer are inhibited due to the spectral mismatch and energy level offset. The optically enhanced flexible AgNW electrode exhibits an improvement of 10.74% in transmittance, yielding flexible organic solar cells with an efficiency of 19.51% and a certified value of 18.69%. This innovative strategy provides a pathway for overcoming plasmon energy losses in plasmonic optoelectronics, opening horizons for highly efficient flexible photovoltaics and plasmonic devices. The parasitic absorption caused by nonradiative damping of plasmonic effects limits the light utilization efficiency of optoelectronics. Here, authors employ green fluorophore and nickel oxide to recycle plasmon energy, achieving maximum device efficiency of 19.51% for flexible organic solar cells.

Topics & Concepts

PlasmonExcitonOrganic solar cellOptoelectronicsMaterials scienceEnergy exchangeNanotechnologyPhotovoltaic systemPhysicsBiologyCondensed matter physicsAtmospheric sciencesEcologyNanowire Synthesis and ApplicationsMolecular Junctions and NanostructuresOrganic Electronics and Photovoltaics
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