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Reducing the Singlet−Triplet Energy Gap by End‐Group π−π Stacking Toward High‐Efficiency Organic Photovoltaics

Guangchao Han, Taiping Hu, Yuanping Yi

2020Advanced Materials139 citationsDOI

Abstract

Abstract To improve the power conversion efficiencies for organic solar cells, it is necessary to enhance light absorption and reduce energy loss simultaneously. Both the lowest singlet (S1) and triplet (T1) excited states need to energertically approach the charge‐transfer state to reduce the energy loss in exciton dissociation and by triplet recombination. Meanwhile, the S1 energy needs to be decreased to broaden light absorption. Therefore, it is imperative to reduce the singlet−triplet energy gap (Δ E ST ), particularly for the narrow‐bandgap materials that determine the device T1 energy. Although maximizing intramolecular push−pull effect can drastically decrease Δ E ST , it inevitably results in weak oscillator strength and light absorption. Herein, large oscillator strength (≈3) and a moderate Δ E ST (0.4−0.5 eV) are found for state‐of‐the‐art A−D−A small‐molecule acceptors (ITIC, IT‐4F, and Y6) owing to modest push−pull effect. Importantly, end‐group π−π stacking commonly in the films can substantially decrease the S1 energy by nearly 0.1 eV, but the T1 energy is hardly changed. The obtained reduction of Δ E ST is crucial to effectively suppress triplet recombination and acquire small exciton dissociation driving force. Thus, end‐group π−π stacking is an effective way to achieve both small energy loss and efficient light absorption for high‐efficiency organic photovoltaics.

Topics & Concepts

Materials scienceOrganic solar cellOscillator strengthStackingSinglet stateBand gapExcitonExcited stateSinglet fissionAbsorption (acoustics)Dissociation (chemistry)Triplet stateOptoelectronicsEnergy conversion efficiencyIntramolecular forcePhotochemistryAtomic physicsChemistryPolymerCondensed matter physicsPhysicsSpectral linePhysical chemistryNuclear magnetic resonanceStereochemistryAstronomyComposite materialOrganic Electronics and PhotovoltaicsPerovskite Materials and ApplicationsOrganic Light-Emitting Diodes Research