Litcius/Paper detail

Significant Impact of Defect Fluctuation on Charge Dynamics in CsPbI<sub>3</sub>: A Study Combining Machine Learning with Quantum Dynamics

Yulong Liu, Wei‐Hai Fang, Run Long

2024The Journal of Physical Chemistry Letters19 citationsDOI

Abstract

In this study, we developed a machine-learned force field for CsPbI 3 using a neural network potential, enabling molecular dynamics simulations (MD) with ab initio accuracy over nanoseconds. This approach, combined with ab initio MD and nonadiabatic MD, was used to study the charge trapping and recombination dynamics in both pristine and defective CsPbI 3 . Our simulations revealed key transitions affecting carrier lifetimes, especially in systems with iodine vacancy and interstitial iodine defects. An iodine trimer, formed when iodine replaces cesium, exhibits a high-frequency phonon mode. This mode enhances nonadiabatic coupling, accelerating charge recombination in defective systems compared to pristine ones. In the iodine vacancy system, recombination times varied significantly due to differences in NA coupling and energy gaps. The interplay between nonadiabatic coupling and pure dephasing time is crucial in determining recombination times for interstitial iodine defects. Our findings highlight the role of defect evolution in perovskites, offering insights for enhancing perovskite performance.

Topics & Concepts

DephasingMolecular dynamicsAb initioCoupling (piping)PhononAb initio quantum chemistry methodsChemical physicsRecombinationNanosecondChemistryMolecular physicsVacancy defectMolecular vibrationMaterials scienceCondensed matter physicsComputational chemistryPhysicsCrystallographyMoleculeQuantum mechanicsLaserMetallurgyOrganic chemistryGeneBiochemistryPerovskite Materials and ApplicationsMachine Learning in Materials ScienceElectronic and Structural Properties of Oxides