Unearthing the Real-Time Excited State Dynamics from Antenna to Rare Earth Ions Using Ultrafast Transient Absorption

Waygen Thor; Hei Yui Kai; Yik Hoi Yeung; Yue Wu; Tsz Lam Cheung; Leo K.B. Tam; Yonghong Zhang; Loïc J. Charbonnière; Peter A. Tanner; Ka Leung Wong

doi:10.1021/jacsau.4c00468

Unearthing the Real-Time Excited State Dynamics from Antenna to Rare Earth Ions Using Ultrafast Transient Absorption

Waygen Thor, Hei Yui Kai, Yik Hoi Yeung, Yue Wu, Tsz Lam Cheung, Leo K.B. Tam, Yonghong Zhang, Loïc J. Charbonnière, Peter A. Tanner, Ka Leung Wong

Research output: Journal article publication › Journal article › Academic research › peer-review

5 Citations (Scopus)

Abstract

The conventional energy transfer pathway in organic lanthanide complexes is purported to be from the excited singlet state of the chromophore to the triplet state and subsequently directly to the emitting state of the trivalent lanthanide ion. In this work, we found that the energy transfer occurs from the triplet state to the nearest energy level, instead of directly to the emitting state of the lanthanide ion. The triplet decay rate for different lanthanide ions follows an energy gap law from the triplet level to the receiving level of the lanthanide ion. Three different categories of complexes were synthesized and inspected using different techniques, demonstrating the universality of our findings. This work renews the insights to conventional findings, highlighting the importance of the energy gap between the triplet state and the nearest lanthanide energy level in optimization of light harvesting. The rationale of ligand design of chromophores should be reconsidered, leading to various applications of lanthanide complexes with enhanced quantum yield and brightness.

Original language	English
Pages (from-to)	3813-3822
Number of pages	10
Journal	JACS Au
Volume	4
Issue number	10
DOIs	https://doi.org/10.1021/jacsau.4c00468
Publication status	Published - 20 Aug 2024

Keywords

Energy transfer
Excited state dynamics
Lanthanide luminescence
Photosensitization mechanism
Time-resolved spectroscopy
Transient absorption

ASJC Scopus subject areas

Analytical Chemistry
Chemistry (miscellaneous)
Physical and Theoretical Chemistry
Organic Chemistry

More information

10.1021/jacsau.4c00468

Cite this

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title = "Unearthing the Real-Time Excited State Dynamics from Antenna to Rare Earth Ions Using Ultrafast Transient Absorption",

abstract = "The conventional energy transfer pathway in organic lanthanide complexes is purported to be from the excited singlet state of the chromophore to the triplet state and subsequently directly to the emitting state of the trivalent lanthanide ion. In this work, we found that the energy transfer occurs from the triplet state to the nearest energy level, instead of directly to the emitting state of the lanthanide ion. The triplet decay rate for different lanthanide ions follows an energy gap law from the triplet level to the receiving level of the lanthanide ion. Three different categories of complexes were synthesized and inspected using different techniques, demonstrating the universality of our findings. This work renews the insights to conventional findings, highlighting the importance of the energy gap between the triplet state and the nearest lanthanide energy level in optimization of light harvesting. The rationale of ligand design of chromophores should be reconsidered, leading to various applications of lanthanide complexes with enhanced quantum yield and brightness.",

keywords = "Energy transfer, Excited state dynamics, Lanthanide luminescence, Photosensitization mechanism, Time-resolved spectroscopy, Transient absorption",

author = "Waygen Thor and Kai, \{Hei Yui\} and Yeung, \{Yik Hoi\} and Yue Wu and Cheung, \{Tsz Lam\} and Tam, \{Leo K.B.\} and Yonghong Zhang and Charbonni{\`e}re, \{Lo{\"i}c J.\} and Tanner, \{Peter A.\} and Wong, \{Ka Leung\}",

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year = "2024",

month = aug,

day = "20",

doi = "10.1021/jacsau.4c00468",

language = "English",

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AU - Thor, Waygen

AU - Kai, Hei Yui

AU - Yeung, Yik Hoi

AU - Wu, Yue

AU - Cheung, Tsz Lam

AU - Tam, Leo K.B.

AU - Zhang, Yonghong

AU - Charbonnière, Loïc J.

AU - Tanner, Peter A.

AU - Wong, Ka Leung

PY - 2024/8/20

Y1 - 2024/8/20

N2 - The conventional energy transfer pathway in organic lanthanide complexes is purported to be from the excited singlet state of the chromophore to the triplet state and subsequently directly to the emitting state of the trivalent lanthanide ion. In this work, we found that the energy transfer occurs from the triplet state to the nearest energy level, instead of directly to the emitting state of the lanthanide ion. The triplet decay rate for different lanthanide ions follows an energy gap law from the triplet level to the receiving level of the lanthanide ion. Three different categories of complexes were synthesized and inspected using different techniques, demonstrating the universality of our findings. This work renews the insights to conventional findings, highlighting the importance of the energy gap between the triplet state and the nearest lanthanide energy level in optimization of light harvesting. The rationale of ligand design of chromophores should be reconsidered, leading to various applications of lanthanide complexes with enhanced quantum yield and brightness.

AB - The conventional energy transfer pathway in organic lanthanide complexes is purported to be from the excited singlet state of the chromophore to the triplet state and subsequently directly to the emitting state of the trivalent lanthanide ion. In this work, we found that the energy transfer occurs from the triplet state to the nearest energy level, instead of directly to the emitting state of the lanthanide ion. The triplet decay rate for different lanthanide ions follows an energy gap law from the triplet level to the receiving level of the lanthanide ion. Three different categories of complexes were synthesized and inspected using different techniques, demonstrating the universality of our findings. This work renews the insights to conventional findings, highlighting the importance of the energy gap between the triplet state and the nearest lanthanide energy level in optimization of light harvesting. The rationale of ligand design of chromophores should be reconsidered, leading to various applications of lanthanide complexes with enhanced quantum yield and brightness.

KW - Energy transfer

KW - Excited state dynamics

KW - Lanthanide luminescence

KW - Photosensitization mechanism

KW - Time-resolved spectroscopy

KW - Transient absorption

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Unearthing the Real-Time Excited State Dynamics from Antenna to Rare Earth Ions Using Ultrafast Transient Absorption

Abstract

Keywords

ASJC Scopus subject areas

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