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Quantifying the Ligand-Induced Triplet Energy Transfer Barrier in a Quantum Dot-Based Upconversion System

Tsumugi Miyashita, Paulina Jaimes, Tianquan Lian, Ming Lee Tang, Zihao Xu

2022The Journal of Physical Chemistry Letters27 citationsDOIOpen Access PDF

Abstract

During photon upconversion, quantum dots (QDs) transfer energy to molecules in solution through a long ligand shell. This insulating ligand shell imparts colloidal stability at the expense of efficient photosensitization. For the first time, we quantify the barrier these aliphatic ligands pose for triplet energy transfer in solution. Using transient absorption spectroscopy, we experimentally measure a small damping coefficient of 0.027 Å–1 for a ligand exceeding 10 carbons in length. The dynamic nature of ligands in solution lowers the barrier to charge or energy transfer compared to organic thin films. In addition, we show that surface ligands shorter than 8 carbons in length allow direct energy transfer from the QD, bypassing the need for a transmitter ligand to mediate energy transfer, leading to a 6.9% upconversion quantum yield compared with 0.01% for ligands with 18 carbons. This experimentally derived insight will enable the design of efficient QD-based photosensitizers for catalysis and energy conversion.

Topics & Concepts

Photon upconversionQuantum dotQuantum yieldLigand (biochemistry)PhotochemistryUltrafast laser spectroscopyChemistryAbsorption (acoustics)ColloidMaterials scienceMoleculeChemical physicsSpectroscopyNanotechnologyOptoelectronicsLuminescencePhysical chemistryFluorescencePhysicsOpticsOrganic chemistryComposite materialQuantum mechanicsBiochemistryReceptorLuminescence Properties of Advanced MaterialsLuminescence and Fluorescent MaterialsQuantum Dots Synthesis And Properties
Quantifying the Ligand-Induced Triplet Energy Transfer Barrier in a Quantum Dot-Based Upconversion System | Litcius