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Low Exciton Binding Energies and Localized Exciton–Polaron States in 2D Tin Halide Perovskites

Kameron R. Hansen, C. Emma McClure, Daniel Powell, Hao‐Chieh Hsieh, Laura Flannery, Kelsey Garden, Edwin J. Miller, Daniel J. King, Sami Sainio, Dennis Nordlund, John S. Colton, Luisa Whittaker‐Brooks

2022Advanced Optical Materials49 citationsDOIOpen Access PDF

Abstract

Abstract Aside from band gap reduction, little is understood about the effect of the tin‐for‐lead substitution on the fundamental optical and optoelectronic properties of metal halide perovskites (MHPs), especially when transitioning from 3D to lower dimensional structures. Herein, we take advantage of the spectroscopic isolation of excitons in 2D MHPs to study the intrinsic differences between lead and tin MHPs. The exciton's spectral fine structure indicates a larger polaron binding energy in tin MHPs. Additionally, the electroabsorption responses of the 2D MHPs demonstrates that tin MHPs have exciton binding energies 1.5–2× lower than that of their lead counterparts. Despite the lower binding energy, the excitons in tin MHPs are more Frenkel‐like with small radii, small polarizabilities, and large dipole moments. These results are interpreted as consequences of small polaron formation and disorder‐induced dipole moments. This work highlights the wide range of intrinsic differences between lead and tin MHPs as well as the complexity of excited states in these systems.

Topics & Concepts

ExcitonTinBinding energyMaterials sciencePolaronDipoleExcited stateCondensed matter physicsBand gapChemical physicsHalideOptoelectronicsAtomic physicsChemistryPhysicsInorganic chemistryQuantum mechanicsElectronMetallurgyOrganic chemistryPerovskite Materials and Applications2D Materials and ApplicationsQuantum Dots Synthesis And Properties
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