Enrichment of molecular antenna triplets amplifies upconverting nanoparticle emission

Enrichment of molecular antenna triplets amplifies upconverting nanoparticle emission

Efficient photon upconversion at low light intensities promises major advances in technologies spanning solar energy harvesting to deep-tissue biophotonics. Here, we discover the critical mechanisms that enable near-infrared dye antennas to significantly enhance performance in lanthanide-doped upcon...

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Bibliographic Details
Published in:Nature photonics Vol. 12; no. 7; pp. 402 - 407
Main Authors: Garfield, David J., Borys, Nicholas J., Hamed, Samia M., Torquato, Nicole A., Tajon, Cheryl A., Tian, Bining, Shevitski, Brian, Barnard, Edward S., Suh, Yung Doug, Aloni, Shaul, Neaton, Jeffrey B., Chan, Emory M., Cohen, Bruce E., Schuck, P. James
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-07-2018
Nature Publishing Group
Subjects:
631/1647/1888
639/301/1019/385
639/638/440/527/1989
639/638/440/527/2047
639/925/357/354
Antennas
Applied and Technical Physics
Density functional theory
Dyes
Energy harvesting
Energy transfer
Hybrids
Luminous intensity
Molecular chains
Nanoparticles
Phosphorescence
Photovoltaic cells
Photovoltaics
Physics
Physics and Astronomy
Quantum Physics
Solar cells
Solar energy
Upconversion
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Summary:Efficient photon upconversion at low light intensities promises major advances in technologies spanning solar energy harvesting to deep-tissue biophotonics. Here, we discover the critical mechanisms that enable near-infrared dye antennas to significantly enhance performance in lanthanide-doped upconverting nanoparticle (UCNP) systems, and leverage these findings to design dye–UCNP hybrids with a 33,000-fold increase in brightness and a 100-fold increase in efficiency over bare UCNPs. We show that increasing the lanthanide content in the UCNPs shifts the primary energy donor from the dye singlet to its triplet, and the resultant triplet states then mediate energy transfer into the nanocrystals. Time-gated phosphorescence, density functional theory, singlet lifetimes and triplet-quenching experiments support these findings. This interplay between the excited-state populations in organic antennas and the composition of UCNPs presents new design rules that overcome the limitations of previous upconverting materials, enabling performances now relevant for photovoltaics, biophotonics and infrared detection. Lanthanide-doped upconverting nanoparticles exhibiting a 33,000 times increase in brightness and a 100 times increase in efficiency over bare upconverting nanoparticles are demonstrated. The findings are relevant in fields from solar energy to biophotonics.
ISSN:1749-4885
1749-4893
DOI:10.1038/s41566-018-0156-x