부산대학교 도서관

Organic solar cells (OSCs) have recently shown a rapid improvement in their performance, bringing power conversion efficiencies (PCEs) closer to the point where commercial applications of the technology become viable. However, the low open-circuit voltage (Voc) of OSCs relative to their optical gap still limits PCEs to below 20%. A key factor contributing to the large Voc deficit in OSCs is non-radiative recombination to spin-triplet excitons, which is widely, but not universally, observed in blends using both fullerene and non-fullerene electron acceptors. Here, we present an experimental framework that combines time resolved optical and magnetic resonance spectroscopies to detect triplet excitons and identify their formation mechanisms. We apply our methodology to two well-studied polymer:fullerene systems, PM6:PC60BM and PTB7-Th:PC60BM, enabling us to selectively investigate distinct triplet formation pathways. In contrast to the more efficient non-fullerene acceptor systems that show only triplet states formed via non-geminate recombination, the fullerene systems also show significant triplet formation via geminate processes. We associate this with electrons trapped at the isolated fullerenes that sit within the alkyl sidechains of the donor polymers. Thus, our model study demonstrates how these complex and overlapping processes can be successfully deconvoluted to reveal the intricacies of triplet generation dynamics in OSC blends.
Comment: 64 pages, 4 main-text figures