Litcius/Paper detail

Dimensionality reduction in machine learning for nonadiabatic molecular dynamics: Effectiveness of elemental sublattices in lead halide perovskites

Wei Bin How, Bipeng Wang, Weibin Chu, Sergiy М. Kovalenko, Alexandre Tkatchenko, Oleg V. Prezhdo

2022The Journal of Chemical Physics11 citationsDOIOpen Access PDF

Abstract

Supervised machine learning (ML) and unsupervised ML have been performed on descriptors generated from nonadiabatic (NA) molecular dynamics (MD) trajectories representing non-radiative charge recombination in CsPbI3, a promising solar cell and optoelectronic material. Descriptors generated from every third atom of the iodine sublattice alone are sufficient for a satisfactory prediction of the bandgap and NA coupling for the use in the NA-MD simulation of nonradiative charge recombination, which has a strong influence on material performance. Surprisingly, descriptors based on the cesium sublattice perform better than those of the lead sublattice, even though Cs does not contribute to the relevant wavefunctions, while Pb forms the conduction band and contributes to the valence band. Simplification of the ML models of the NA-MD Hamiltonian achieved by the present analysis helps to overcome the high computational cost of NA-MD through ML and increase the applicability of NA-MD simulations.

Topics & Concepts

Hamiltonian (control theory)Molecular dynamicsDimensionality reductionWave functionChemistryBand gapConduction bandValence (chemistry)HalideAtom (system on chip)FullereneCurse of dimensionalityMolecular physicsComputational chemistryPhysicsMachine learningAtomic physicsQuantum mechanicsComputer scienceElectronMathematicsInorganic chemistryMathematical optimizationEmbedded systemPerovskite Materials and ApplicationsMachine Learning in Materials ScienceChalcogenide Semiconductor Thin Films