Exciton Binding Energy in Organic Polymers: Experimental Considerations and Tuning Prospects

Kashani, Somayeh; Rech, Jeromy James; Liu, Tuo; Baustert, Kyle; Ghaffari, Abbas; Angunawela, Indunil; Xiong, Yuan; Dinku, Abay; You, Wei; Graham, Kenneth; Ade, Harald

doi:10.1002/aenm.202302837

Cited by 8 publications

(1 citation statement)

References 121 publications

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“…Relatively little research has been done on vacancy-ordered perovskites for solar cells. Studies have shown that Cs 2 TiX 6 (X = Br and I) possesses multiple desirable attributes including good stability and high optical absorption coefficients in the visible light ranges. − More recently, Zhao et al and Reyes-Francis et al, respectively, pointed out the ease of synthesis and high power conversion efficiency (PCE) of Cs 2 TiX 6 . , The impact of large exciton binding energy in Cs 2 TiX 6 may potentially be mitigated through atomic substitution or by changing the dielectric environment of the insulating organic layer. − The aforementioned discussions suggest that Cs 2 TiX 6 holds the potential for use in solar cells. However, existing calculations and experiments have proven that both Cs 2 TiBr 6 and Cs 2 TiI 6 have some shortcomings that limit their further applications. , First, these two materials have quasi-direct bandgaps with indirect bandgaps between Γ (valence band maximum, VBM) and X (conduction band minimum, CBM), which are detrimental to their photovoltaic performance .…”

Section: Introductionmentioning

confidence: 99%

Intrinsic Defects of Vacancy-Ordered Perovskite Cs₂TiIBr₅ for Solar Cells

Yang,

Zhou,

Chen

et al. 2024

J. Phys. Chem. C

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Vacancy-ordered perovskites A 2 M 4+ X 6 have shown potential in luminescence and photocatalytic applications, while limited research on them for solar cells exists. Previous studies have demonstrated that Cs 2 TiI 6 and Cs 2 TiBr 6 possess good stability and high optical absorption coefficients in the visible light range but have undesirable bandgap characteristics. In response to the shortcoming, we investigated the bandgap properties of Cs 2 TiI x Br 6−x and further conducted a comprehensive analysis of the intrinsic defect properties and structural stability of Cs 2 TiIBr 5 and Cs 2 TiI 2 Br 4 . We find that as-yet-unsynthesized Cs 2 TiIBr 5 has a direct bandgap of 1.39 eV. Additionally, our results reveal that Cs 2 TiIBr 5 is thermodynamically stable and exhibits good defect tolerance. Notably, Cs 2 TiIBr 5 is expected to exhibit n-type conductivity with a considerable concentration of charge carriers under Ti-rich/Cs-rich/I-poor chemical potential conditions. Overall, our findings provide valuable theoretical insights that facilitate the experimental synthesis of new vacancy-ordered perovskites.

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Section: Introductionmentioning

confidence: 99%

Intrinsic Defects of Vacancy-Ordered Perovskite Cs₂TiIBr₅ for Solar Cells

Yang,

Zhou,

Chen

et al. 2024

J. Phys. Chem. C

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Steric hindrance induced low exciton binding energy enables low‐driving‐force organic solar cells

Hu,

Zheng,

Wang

et al. 2024

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Exciton binding energy (Eb) has been regarded as a critical parameter in charge separation during photovoltaic conversion. Minimizing the Eb of the photovoltaic materials can facilitate the exciton dissociation in low‐driving force organic solar cells (OSCs) and thus improve the power conversion efficiency (PCE); nevertheless, diminishing the Eb with deliberate design principles remains a significant challenge. Herein, bulky side chain as steric hindrance structure was inserted into Y‐series acceptors to minimize the Eb by modulating the intra‐ and intermolecular interaction. Theoretical and experimental results indicate that steric hindrance‐induced optimal intra‐ and intermolecular interaction can enhance molecular polarizability, promote electronic orbital overlap between molecules, and facilitate delocalized charge transfer pathways, thereby resulting in a low Eb. The conspicuously reduced Eb obtained in Y‐ChC5 with pinpoint steric hindrance modulation can minimize the detrimental effects on exciton dissociation in low‐driving‐force OSCs, achieving a remarkable PCE of 19.1% with over 95% internal quantum efficiency. Our study provides a new molecular design rationale to reduce the Eb.

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Linker‐Mediated Delocalized Excited States in Dimeric Acceptors Enable Efficient Exciton Dissociation with Negligible Energy‐Level Offsets

Shi,

Yang,

et al. 2024

Angewandte Chemie

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Efficient exciton dissociation at low energy offsets is key to overcoming voltage losses in organic solar cells. In this work, we developed two dimeric acceptors, i‐YT and o‐YT, by precisely controlling the position of an asymmetric electron‐donating linker. It induced the foldamer conformation of i‐YT with a para linkage (relative to the dicyano groups), while retaining the unfold conformation for o‐YT. This subtle structural modification influenced the molecular assembly properties, enabled near‐zero energy offset exciton dissociation and power conversion efficiencies exceeding 18% for i‐YT based organic solar cells. Detailed excitonic dynamics further revealed that the linker position critically influences three processes: the formation of delocalized singlet excited states, ultrafast charge transfer (~5 ps) in solid blends, and the suppression of exciton recombination. Additionally, devices based on i‐YT demonstrated outstanding long‐term stability, retaining over 85% of their initial efficiency after 1,400 hours of continuous illumination. These findings introduce a new class of dimeric acceptors that combine high efficiency with exceptional stability, offering a promising pathway toward low‐energy‐loss organic photovoltaics.

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Exciton Binding Energy in Organic Polymers: Experimental Considerations and Tuning Prospects

Cited by 8 publications

References 121 publications

Intrinsic Defects of Vacancy-Ordered Perovskite Cs₂TiIBr₅ for Solar Cells

Intrinsic Defects of Vacancy-Ordered Perovskite Cs₂TiIBr₅ for Solar Cells

Steric hindrance induced low exciton binding energy enables low‐driving‐force organic solar cells

Linker‐Mediated Delocalized Excited States in Dimeric Acceptors Enable Efficient Exciton Dissociation with Negligible Energy‐Level Offsets

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Exciton Binding Energy in Organic Polymers: Experimental Considerations and Tuning Prospects

Cited by 8 publications

References 121 publications

Intrinsic Defects of Vacancy-Ordered Perovskite Cs2TiIBr5 for Solar Cells

Intrinsic Defects of Vacancy-Ordered Perovskite Cs2TiIBr5 for Solar Cells

Steric hindrance induced low exciton binding energy enables low‐driving‐force organic solar cells

Linker‐Mediated Delocalized Excited States in Dimeric Acceptors Enable Efficient Exciton Dissociation with Negligible Energy‐Level Offsets

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Intrinsic Defects of Vacancy-Ordered Perovskite Cs₂TiIBr₅ for Solar Cells

Intrinsic Defects of Vacancy-Ordered Perovskite Cs₂TiIBr₅ for Solar Cells