Author
Listed:
- Sanyang Han
(University of Cambridge)
- Renren Deng
(University of Cambridge
Zhejiang University)
- Qifei Gu
(University of Cambridge)
- Limeng Ni
(University of Cambridge)
- Uyen Huynh
(University of Cambridge)
- Jiangbin Zhang
(University of Cambridge
Imperial College London
National University of Defense Technology)
- Zhigao Yi
(National University of Singapore)
- Baodan Zhao
(University of Cambridge
Zhejiang University)
- Hiroyuki Tamura
(The University of Tokyo)
- Anton Pershin
(University of Mons)
- Hui Xu
(Heilongjiang University)
- Zhiyuan Huang
(University of California, Riverside)
- Shahab Ahmad
(Indian Institute of Technology Jodhpur)
- Mojtaba Abdi-Jalebi
(University of Cambridge
University College London)
- Aditya Sadhanala
(University of Cambridge)
- Ming Lee Tang
(University of California, Riverside)
- Artem Bakulin
(Imperial College London)
- David Beljonne
(University of Mons)
- Xiaogang Liu
(National University of Singapore
National University of Singapore
Joint School of National University of Singapore and Tianjin University, International Campus of Tianjin University)
- Akshay Rao
(University of Cambridge)
Abstract
The generation, control and transfer of triplet excitons in molecular and hybrid systems is of great interest owing to their long lifetime and diffusion length in both solid-state and solution phase systems, and to their applications in light emission1, optoelectronics2,3, photon frequency conversion4,5 and photocatalysis6,7. Molecular triplet excitons (bound electron–hole pairs) are ‘dark states’ because of the forbidden nature of the direct optical transition between the spin-zero ground state and the spin-one triplet levels8. Hence, triplet dynamics are conventionally controlled through heavy-metal-based spin–orbit coupling9–11 or tuning of the singlet–triplet energy splitting12,13 via molecular design. Both these methods place constraints on the range of properties that can be modified and the molecular structures that can be used. Here we demonstrate that it is possible to control triplet dynamics by coupling organic molecules to lanthanide-doped inorganic insulating nanoparticles. This allows the classically forbidden transitions from the ground-state singlet to excited-state triplets to gain oscillator strength, enabling triplets to be directly generated on molecules via photon absorption. Photogenerated singlet excitons can be converted to triplet excitons on sub-10-picosecond timescales with unity efficiency by intersystem crossing. Triplet exciton states of the molecules can undergo energy transfer to the lanthanide ions with unity efficiency, which allows us to achieve luminescent harvesting of the dark triplet excitons. Furthermore, we demonstrate that the triplet excitons generated in the lanthanide nanoparticle–molecule hybrid systems by near-infrared photoexcitation can undergo efficient upconversion via a lanthanide–triplet excitation fusion process: this process enables endothermic upconversion and allows efficient upconversion from near-infrared to visible frequencies in the solid state. These results provide a new way to control triplet excitons, which is essential for many fields of optoelectronic and biomedical research.
Suggested Citation
Sanyang Han & Renren Deng & Qifei Gu & Limeng Ni & Uyen Huynh & Jiangbin Zhang & Zhigao Yi & Baodan Zhao & Hiroyuki Tamura & Anton Pershin & Hui Xu & Zhiyuan Huang & Shahab Ahmad & Mojtaba Abdi-Jalebi, 2020.
"Lanthanide-doped inorganic nanoparticles turn molecular triplet excitons bright,"
Nature, Nature, vol. 587(7835), pages 594-599, November.
Handle:
RePEc:nat:nature:v:587:y:2020:i:7835:d:10.1038_s41586-020-2932-2
DOI: 10.1038/s41586-020-2932-2
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Citations
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Cited by:
- Zhao Jiang & Liangrui He & Zhiwen Yang & Huibin Qiu & Xiaoyuan Chen & Xujiang Yu & Wanwan Li, 2023.
"Ultra-wideband-responsive photon conversion through co-sensitization in lanthanide nanocrystals,"
Nature Communications, Nature, vol. 14(1), pages 1-10, December.
- Huai Chen & Mingyang Wei & Yantao He & Jehad Abed & Sam Teale & Edward H. Sargent & Zhenyu Yang, 2022.
"Germanium silicon oxide achieves multi-coloured ultra-long phosphorescence and delayed fluorescence at high temperature,"
Nature Communications, Nature, vol. 13(1), pages 1-9, December.
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