Litcius/Paper detail

Tunneling-Driven Marcus-Inverted Triplet Energy Transfer in a Two-Dimensional Perovskite

Angana De, Carlos Mora Perez, Aihui Liang, Kang Wang, Letian Dou, Oleg V. Prezhdo, Libai Huang

2024Journal of the American Chemical Society37 citationsDOI

Abstract

Quantum tunneling, a phenomenon that allows particles to pass through potential barriers, can play a critical role in energy transfer processes. Here, we demonstrate that the proper design of organic-inorganic interfaces in two-dimensional (2D) hybrid perovskites allows for efficient triplet energy transfer (TET), where quantum tunneling of the excitons is the key driving force. By employing temperature-dependent and time-resolved photoluminescence and pump-probe spectroscopy techniques, we establish that triplet excitons can transfer from the inorganic lead-iodide sublattices to the pyrene ligands with rapid and weakly temperature-dependent characteristic times of approximately 50 ps. The energy transfer rates obtained based on the Marcus theory and first-principles calculations show good agreement with the experiments, indicating that the efficient tunneling of triplet excitons within the Marcus-inverted regime is facilitated by high-frequency molecular vibrations. These findings offer valuable insights into how one can effectively manipulate the energy landscape in 2D hybrid perovskites for energy transfer and the creation of diverse excitonic states.

Topics & Concepts

ChemistryQuantum tunnellingMarcus theoryPerovskite (structure)Energy transferTransfer (computing)Chemical physicsOptoelectronicsCrystallographyQuantum mechanicsKineticsReaction rate constantPhysicsParallel computingComputer sciencePerovskite Materials and ApplicationsSpectroscopy and Quantum Chemical StudiesElectrochemical Analysis and Applications