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Grain boundary sliding and distortion on a nanosecond timescale induce trap states in CsPbBr<sub>3</sub>: <i>ab initio</i> investigation with machine learning force field

Dongyu Liu, Yifan Wu, Andrey S. Vasenko, Oleg V. Prezhdo

2022Nanoscale43 citationsDOI

Abstract

GB on a nanosecond timescale, which is comparable with the carrier recombination time. We demonstrate that the GB slides spontaneously within a few picoseconds increasing the band gap. Subsequent structural oscillations dynamically produce midgap trap states through Pb-Pb interactions across the GB. After several hundred picoseconds, structural distortions start to occur, increasing the occurrence of deep midgap states. We identify a distinct correlation of the average Pb-Pb distance and fluctuations in the ion coordination numbers with the appearance of the midgap states. Suppressing GB distortions through annealing and breaking up Pb-Pb dimers by passivation can efficiently alleviate the detrimental effects of GBs in perovskites. The study provides new insights into passivation of the detrimental GB defects, and demonstrates that structural and charge carrier dynamics in perovskites are intimately coupled.

Topics & Concepts

NanosecondGrain boundaryTrap (plumbing)Ab initioDistortion (music)Force field (fiction)Field (mathematics)Boundary (topology)Molecular dynamicsMaterials scienceAb initio quantum chemistry methodsChemical physicsPhysicsMolecular physicsCondensed matter physicsAtomic physicsOpticsQuantum mechanicsMoleculeOptoelectronicsLaserMetallurgyMathematicsPure mathematicsMicrostructureMeteorologyMathematical analysisAmplifierCMOSPerovskite Materials and ApplicationsSolid-state spectroscopy and crystallographyChalcogenide Semiconductor Thin Films
Grain boundary sliding and distortion on a nanosecond timescale induce trap states in CsPbBr<sub>3</sub>: <i>ab initio</i> investigation with machine learning force field | Litcius