In organic solar cells (OSCs), the nonradiative voltage loss (Δ V nr ) has been identified as a critical factor for the relatively lower open-circuit voltage. Under open-circuit conditions, most of the charge recombination processes occur via the triplet exciton state, underscoring the importance of the energy structures concerning the local exciton (LE) and charge transfer (CT) spin states. In this Letter, we propose a five-state model to explore the spin state energy structures to reduce Δ V nr . Our calculations reveal that, to minimize Δ V nr , the spin singlet state for LE should possess a lower energy than the triplet state, E S 1 < E T 1 . In contrast, the energies of the CT spin states have a negligible effect on Δ V nr . We identify the best energy structure as E S 1 < E T 1 ∼ E CT 1 /CT 3 . Moreover, our calculations demonstrate that strong couplings between these spin states, particularly involving spin flip, can effectively mitigate Δ V nr . These findings present novel insights for the advancement of OSCs.
Keyphrases
- density functional theory
- solar cells
- room temperature
- molecular dynamics
- contrast enhanced
- single molecule
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- dual energy
- transition metal
- energy transfer
- positron emission tomography
- magnetic resonance imaging
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