Two Biexciton Types Coexisting in Coupled Quantum Dot Molecules

Two Biexciton Types Coexisting in Coupled Quantum Dot Molecules

Coupled colloidal quantum dot molecules (CQDMs) are an emerging class of nanomaterials, manifesting two coupled emission centers and thus introducing additional degrees of freedom for designing quantum-dot-based technologies. The properties of multiply excited states in these CQDMs are crucial to th...

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Bibliographic Details
Published in:ACS nano Vol. 17; no. 15; pp. 14990 - 15000
Main Authors: Frenkel, Nadav, Scharf, Einav, Lubin, Gur, Levi, Adar, Panfil, Yossef E., Ossia, Yonatan, Planelles, Josep, Climente, Juan I., Banin, Uri, Oron, Dan
Format: Journal Article
Language:English
Published: United States American Chemical Society 08-08-2023
Subjects:
Biexcitons
SPAD arrays
Hybridization
Quantum dots
Binding energy
Single-particle spectroscopy
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Summary:Coupled colloidal quantum dot molecules (CQDMs) are an emerging class of nanomaterials, manifesting two coupled emission centers and thus introducing additional degrees of freedom for designing quantum-dot-based technologies. The properties of multiply excited states in these CQDMs are crucial to their performance as quantum light emitters, but they cannot be fully resolved by existing spectroscopic techniques. Here we study the characteristics of biexcitonic species, which represent a rich landscape of different configurations essentially categorized as either segregated or localized biexciton states. To this end, we introduce an extension of Heralded Spectroscopy to resolve the different biexciton species in the prototypical CdSe/CdS CQDM system. By comparing CQDMs with single quantum dots and with nonfused quantum dot pairs, we uncover the coexistence and interplay of two distinct biexciton species: A fast-decaying, strongly interacting biexciton species, analogous to biexcitons in single quantum dots, and a long-lived, weakly interacting species corresponding to two nearly independent excitons. The two biexciton types are consistent with numerical simulations, assigning the strongly interacting species to two excitons localized at one side of the quantum dot molecule and the weakly interacting species to excitons segregated to the two quantum dot molecule sides. This deeper understanding of multiply excited states in coupled quantum dot molecules can support the rational design of tunable single- or multiple-photon quantum emitters.
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ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.3c03921