Litcius/Paper detail

Selenium‐Substitution Asymmetric Acceptor Enables Efficient Binary Organic Solar Cells over 18.3% via Regulating Molecular Stacking and Phase Separation

Jingyu Shi, Zhenyu Chen, Hui Liu, Yi Qiu, Shuncheng Yang, Wei Song, Ziyi Ge

2023Advanced Energy Materials59 citationsDOI

Abstract

Abstract Substantial efforts of A–DA′D–A type non‐fullerene acceptors (NFAs) molecular design have impelled power conversion efficiency (PCE) of single junction organic solar cells (OSCs) to exceed 19%. Asymmetric geometry strategy, selenium‐substitution, and end‐group engineering are proven to be effective modification methods. Here, two novel selenium substitution asymmetric NFAs, AsymSSe‐2F, and AsymSSe‐2Cl, are synthesized to investigate the synergistic modification effects on device performance compared with symmetric Y6. When blending AsymSSe‐2F with the wide‐bandgap and high crystallinity polymer D18, a remarkable PCE of 18.31% is yielded, and an excellent fill factor of 79.46% is achieved, which is attributed to the broadened absorption, enhanced π – π stacking, balanced carrier mobilities, and fine phase‐separation morphology. Notably, among the reported selenium‐substituted asymmetric NFAs based OSCs, especially combined with the seldom‐reported D18, this PCE is top‐ranked in binary bulk heterojunction organic solar cells. This work indicates that the combined modification of asymmetric geometry and selenium substitution in NFAs is a promising strategy for fabricating high performance OSCs.

Topics & Concepts

StackingMaterials scienceOrganic solar cellSeleniumCrystallinityEnergy conversion efficiencyAcceptorPolymer solar cellSubstitution (logic)Chemical engineeringBand gapPhase (matter)PolymerOptoelectronicsOrganic chemistryChemistryComposite materialMetallurgyCondensed matter physicsPhysicsEngineeringProgramming languageComputer scienceOrganic Electronics and PhotovoltaicsPerovskite Materials and ApplicationsConducting polymers and applications