Xiafei Cheng scite author profile

Three narrow band gap (NBG) acceptors, namely, TTDTC-0F, TTDTC-2F, and TTDTC-4F, were synthesized by introducing a strong electrondonating unit as the central core. The enhanced intramolecular charge transfer endows the three acceptors with high-lying highest occupied molecular orbitals (HOMOs) of ∼−5.20 eV and ultranarrow band gaps (∼1.25 eV). When blended with poly(3hexylthiophene) (P3HT), all organic solar cells (OSCs) exhibited a broad photoresponse from 300 to ∼1000 nm. Among them, P3HT:TTDTC-4F-based devices achieved the highest efficiency of 7.81% with a prominent J sc exceeding 22 mA•cm −2 . This study demonstrates that the conjugated molecules with high HOMOs can also function as acceptor materials for P3HT-based OSCs, which opens a window to increase PCEs of P3HT-based OSCs in the future to the level of the devices based on the current state-of-the-art polymer donor materials.

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Implications of Crystallization Temperatures of Organic Small Molecules in Optimizing Nonfullerene Solar Cell Performance

Cheng

Liang

et al. 2021

ACS Appl. Energy Mater.

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Crystallization behaviors of both small-molecule donors and acceptors are critical yet complicated factors that determine the microstructure of all small-molecule organic solar cells. To achieve desired photovoltaic performance, it is of vital importance to elucidate the role of key crystallization parameters of each component in optimizing the morphology of blend films. To this end, four binary blends based on crystalline donors with various crystallization temperatures (namely DRTT-R, DRTT-T, DRTT-2T, and DRTT-TT) and a weakly crystalline acceptor N3 were selected. We determined the crystallization onset temperature (T c,onset) and aggregation transition temperature of the small molecules in neat/blend films by temperature-dependent X-ray diffraction and UV–vis measurements. Based on the detailed analysis of molecular crystallization, film morphology evolution, and device performance, a strong correlation between the T c,onset of photoactive materials and optimal thermal annealing (TA) conditions for device performance was established across these systems. Guided by this finding, a two-step TA approach was used to realize DRTT-T:N3 blend films with highly ordered molecular packing and appropriate phase separation morphology, thereby yielding a high power conversion efficiency of 13.21%. Our study demonstrates that using simple crystallization parameters, that is, T c,onset, can rationalize the annealing protocols, which is instructive for promoting the performance of all small-molecule electronic blends.

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“Twisted” small molecule donors with enhanced intermolecular interactions in the condensed phase towards efficient and thick-film all-small-molecule organic solar cells

Cheng

Liang

et al. 2023

J. Mater. Chem. A

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Xiafei Cheng

“Twisted” conjugated molecules as donor materials for efficient all-small-molecule organic solar cells processed with tetrahydrofuran

P3HT-Based Organic Solar Cells with a Photoresponse to 1000 nm Enabled by Narrow Band Gap Nonfullerene Acceptors with High HOMO Levels

Implications of Crystallization Temperatures of Organic Small Molecules in Optimizing Nonfullerene Solar Cell Performance

“Twisted” small molecule donors with enhanced intermolecular interactions in the condensed phase towards efficient and thick-film all-small-molecule organic solar cells

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