Litcius/Paper detail

Entropy-Gated Thermally Activated Delayed Emission Lifetime in Phenanthrene-Functionalized CsPbBr<sub>3</sub> Perovskite Nanocrystals

Shan He, Yaoyao Han, Jingwei Guo, Kaifeng Wu

2021The Journal of Physical Chemistry Letters31 citationsDOI

Abstract

Charge and electronic energy transfer form the basis of many natural and artificial energy transduction systems. The energy landscapes that drive these transfer processes are often constructed from enthalpy changes. In contrast, the entropic effect, although occasionally invoked to explain some excited-state dynamics, has rarely been used to actively control charge/energy flow. Here we derive a generic formula describing how entropy can quantitatively gate the thermally activated delayed emission lifetime in semiconductor nanocrystal–molecular triplet acceptor complexes and experimentally verify the model using highly emissive, quantum-confined CsPbBr3 nanocrystals surface-functionalized with multiple phenanthrene triplet acceptors. Triplet energy transfer from photoexcited CsPbBr3 nanocrystals to phenanthrene is followed by thermally activated repopulation of nanocrystal excitons, leading to delayed nanocrystal emission. The lifetime of delayed emission increases with the phenanthrene/nanocrystal ratio, due to lowering of the free energy of the acceptor state by entropic gain. This study points toward a direction of using entropy to artificially design donor–acceptor light-emitting materials with predetermined excited-state lifetimes.

Topics & Concepts

NanocrystalExcited stateExcitonMaterials scienceAcceptorPhenanthreneBiexcitonChemical physicsPerovskite (structure)Quantum dotNanotechnologyAtomic physicsChemistryCondensed matter physicsPhysicsCrystallographyEnvironmental chemistryPerovskite Materials and ApplicationsOrganic Light-Emitting Diodes ResearchQuantum Dots Synthesis And Properties