Spectrally Resolved Dynamics of Energy Transfer in Quantum-Dot Assemblies: Towards Engineered Energy Flows in Artificial Materials

Crooker, S. A.; Hollingsworth, Jennifer A.; Tretiak, Sergei; Klimov, Victor I.

doi:10.1103/physrevlett.89.186802

articlePhysical Review LettersOct 14, 2002Closed access

Spectrally Resolved Dynamics of Energy Transfer in Quantum-Dot Assemblies: Towards Engineered Energy Flows in Artificial Materials

SAS. A. Crooker JAJennifer A. Hollingsworth STSergei Tretiak VIVictor I. Klimov

Los Alamos National Laboratory

PubMed

Indexed incrossrefpubmed

Abstract

We report on the dynamics of resonant energy transfer in monodisperse, mixed-size, and energy-gradient (layered) assemblies of CdSe nanocrystal quantum dots. Time-resolved and spectrally resolved photoluminescence directly reveals the energy-dependent transfer rate of excitons from smaller to larger dots via electrostatic coupling. The data show a rapid (0.7-1.9 ns) energy transfer directly across a large tens-of-meV energy gap (i.e., between dots of disparate size), and suggest that interdot energy transfer can approach picosecond time scales in structurally optimized systems.

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Topics & keywords

Topics

Keywords

Quantum dot
Photoluminescence
Exciton
Picosecond
Energy transfer
Materials science
Nanocrystal
Coupling (piping)

UN Sustainable Development Goals

Affordable and clean energy

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