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Stacking Arrangement and Orientation of Aromatic Cations Tune Bandgap and Charge Transport of 2D Organic‐Inorganic Hybrid Perovskites

Jing Lai, Renlong Zhu, Junjun Tan, Zhe Yang, Shuji Ye

2023Small13 citationsDOIOpen Access PDF

Abstract

Abstract Chemical modifications on aromatic spacers of 2D perovskites have been demonstrated to be an effective strategy to simultaneously improve optoelectronic properties and stability. However, its underlying mechanism is poorly understood. By using 2D phenyl‐based perovskites ([C 6 H 5 (CH 2 ) m NH 3 ] 2 PbI 4 ) as models, the authors have revealed how the chemical nature of aromatic cations tunes the bandgap and charge transport of 2D perovskites by utilizing sum‐frequency generation vibrational spectroscopy to determine the stacking arrangement and orientation of aromatic cations. It is found that the antiparallel slip‐stack arrangement of phenyl rings between adjacent layers induces an indirect band gap, resulting in anomalous carrier dynamics. Incorporation of the CH 2 moiety causes stacking rearrangement of the phenyl ring and thus promotes an indirect to direct bandgap transition. In direct‐bandgap perovskites, higher carrier mobility correlates with a larger orientation angle of the phenyl ring. Further optimizing the orientation angle by introducing a para‐substituted element in a phenyl ring, higher carrier mobility is obtained. This work highlights the importance of leveraging stacking arrangement and orientation of the aromatic cations to tune the photophysical properties, which opens up an avenue for advancing high‐performance 2D perovskites optoelectronics via molecular engineering.

Topics & Concepts

StackingBand gapMaterials scienceAntiparallel (mathematics)MoietyRing (chemistry)CrystallographyChemical physicsElectron mobilityOptoelectronicsChemistryStereochemistryOrganic chemistryPhysicsQuantum mechanicsMagnetic fieldPerovskite Materials and Applications2D Materials and ApplicationsGa2O3 and related materials
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