Enabling Förster Resonance Energy Transfer from Large Nanocrystals through Energy Migration

Renren Deng; Juan Wang; Runfeng Chen; Wei Huang; Xiaogang Liu

doi:10.1021/jacs.6b09349

Enabling Förster Resonance Energy Transfer from Large Nanocrystals through Energy Migration

Renren Deng, Juan Wang, Runfeng Chen, Wei Huang, Xiaogang Liu

Research output: Contribution to journal › Article › peer-review

113 Scopus citations

Abstract

The stringent distance dependence of Förster resonance energy transfer (FRET) has limited the ability of an energy donor to donate excitation energy to an acceptor over a Förster critical distance (R₀) of 2-6 nm. This poses a fundamental size constraint (<8 nm or ∼4R₀) for experimentation requiring particle-based energy donors. Here, we describe a spatial distribution function model and theoretically validate that the particle size constraint can be mitigated through coupling FRET with a resonant energy migration process. By combining excitation energy migration and surface trapping, we demonstrate experimentally an over 600-fold enhancement over acceptor emission for large nanocrystals (30 nm or ∼15R₀) with surface-anchored molecular acceptors. Our work shows that the migration-coupled approach can dramatically improve sensitivity in FRET-limited measurement, with potential applications ranging from facile photochemical synthesis to biological sensing and imaging at the single-molecule level.

Original language	English
Pages (from-to)	15972-15979
Number of pages	8
Journal	Journal of the American Chemical Society
Volume	138
Issue number	49
DOIs	https://doi.org/10.1021/jacs.6b09349
State	Published - 14 Dec 2016
Externally published	Yes

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title = "Enabling F{\"o}rster Resonance Energy Transfer from Large Nanocrystals through Energy Migration",

abstract = "The stringent distance dependence of F{\"o}rster resonance energy transfer (FRET) has limited the ability of an energy donor to donate excitation energy to an acceptor over a F{\"o}rster critical distance (R0) of 2-6 nm. This poses a fundamental size constraint (<8 nm or ∼4R0) for experimentation requiring particle-based energy donors. Here, we describe a spatial distribution function model and theoretically validate that the particle size constraint can be mitigated through coupling FRET with a resonant energy migration process. By combining excitation energy migration and surface trapping, we demonstrate experimentally an over 600-fold enhancement over acceptor emission for large nanocrystals (30 nm or ∼15R0) with surface-anchored molecular acceptors. Our work shows that the migration-coupled approach can dramatically improve sensitivity in FRET-limited measurement, with potential applications ranging from facile photochemical synthesis to biological sensing and imaging at the single-molecule level.",

author = "Renren Deng and Juan Wang and Runfeng Chen and Wei Huang and Xiaogang Liu",

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T1 - Enabling Förster Resonance Energy Transfer from Large Nanocrystals through Energy Migration

AU - Deng, Renren

AU - Wang, Juan

AU - Chen, Runfeng

AU - Huang, Wei

AU - Liu, Xiaogang

PY - 2016/12/14

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AB - The stringent distance dependence of Förster resonance energy transfer (FRET) has limited the ability of an energy donor to donate excitation energy to an acceptor over a Förster critical distance (R0) of 2-6 nm. This poses a fundamental size constraint (<8 nm or ∼4R0) for experimentation requiring particle-based energy donors. Here, we describe a spatial distribution function model and theoretically validate that the particle size constraint can be mitigated through coupling FRET with a resonant energy migration process. By combining excitation energy migration and surface trapping, we demonstrate experimentally an over 600-fold enhancement over acceptor emission for large nanocrystals (30 nm or ∼15R0) with surface-anchored molecular acceptors. Our work shows that the migration-coupled approach can dramatically improve sensitivity in FRET-limited measurement, with potential applications ranging from facile photochemical synthesis to biological sensing and imaging at the single-molecule level.

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Enabling Förster Resonance Energy Transfer from Large Nanocrystals through Energy Migration

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