What does this research mean for the field?

A noncoordinating substituent modulation strategy significantly reduces the nonradiative transition rate in uranyl organic complexes, boosting their photoluminescence quantum yield to record levels and enabling highly sensitive X-ray detection and high-resolution imaging. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The study aims to enhance the photoluminescence quantum yield of uranyl organic complexes through a noncoordinating substituent modulation strategy.

June 1, 2026

Noncoordinating Substituent Modulation Strategy Lights Up Uranyl Organic Complexes for Sensitive X-ray Detection and Imaging

Key Points

The study aims to enhance the photoluminescence quantum yield of uranyl organic complexes through a noncoordinating substituent modulation strategy.
Proposed a modulation strategy for electronic structure of uranyl organic complexes.
Evaluated changes in nonradiative transition rates and photoluminescence quantum yields.
Assessed the performance of scintillator films for X-ray imaging.
Achieved over 60-fold reduction in nonradiative transition rate, increasing PLQY from 0.24% to 42.8%.
Identified UOC 3 as a leading uranium-based scintillator for X-ray detection.
Developed a scintillator film with high spatial resolution of approximately 5 lp mm–1 for X-ray imaging.

Abstract

Uranyl organic complexes (UOCs) commonly exhibit low photoluminescence quantum yield (PLQY) due to their high nonradiative transition rate (knr) caused by jammed ligand-to-uranyl energy transfer as well as vibrational energy dissipation derived from the flexible structure. Herein, we proposed a noncoordinating substituent modulation strategy to regulate the electronic structure and the stacking mode of UOCs. An over 60-fold reduction in knr boosts the PLQY from 0.24% (UOC 1) to 42.8% (UOC 3), the highest value in heteroleptic UOCs. With this benefit, UOC 3 emerges as a top-performing uranium-based scintillator for sensitive X-ray detection. Furthermore, a uniform and flexible scintillator film prepared from UOC 3 exhibited a high spatial resolution of approximately 5 lp mm–1 for efficient X-ray imaging.

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Noncoordinating Substituent Modulation Strategy Lights Up Uranyl Organic Complexes for Sensitive X-ray Detection and Imaging

Key Points

Abstract

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