Your search keyword '"Yao, Xiaokang"' showing total 6 results

1. Narrowband room temperature phosphorescence of closed-loop molecules through the multiple resonance effect.

Author

Yao X, Li Y, Shi H, Yu Z, Wu B, Zhou Z, Zhou C, Zheng X, Tang M, Wang X, Ma H, Meng Z, Huang W, and An Z

Abstract

Luminescent materials with narrowband emission show great potential for diverse applications in optoelectronics. Purely organic phosphors with room-temperature phosphorescence (RTP) have made significant success in rationally manipulating quantum efficiency, lifetimes, and colour gamut in the past years, but there is limited attention on the purity of the RTP colours. Herein we report a series of closed-loop molecules with narrowband phosphorescence by multiple resonance effect, which significantly improves the colour purity of RTP. Phosphors show narrowband phosphorescence with full width at half maxima (FWHM) of 30 nm after doping into a rigid benzophenone matrix under ambient conditions, of which the RTP efficiency reaches 51.8%. At 77 K, the FWHM of phosphorescence is only 11 nm. Meanwhile, the colour of narrowband RTP can be tuned from sky blue to green with the modification of methyl groups. Additionally, the potential applications in X-ray imaging and display are demonstrated. This work not only outlines a design principle for developing narrowband RTP materials but also makes a major step forward extending the potential applications of narrowband luminescent materials in optoelectronics., (© 2024. The Author(s).)

Published

2024

2. Boosting organic phosphorescence in adaptive host-guest materials by hyperconjugation.

Author

Ma H, Fu L, Yao X, Jiang X, Lv K, Ma Q, Shi H, An Z, and Huang W

Abstract

Phosphorescence is ubiquitous in heavy atom-containing organic phosphors, which attracts considerable attention in optoelectronics and bioelectronics. However, heavy atom-free organic materials with efficient phosphorescence are rare under ambient conditions. Herein, we report a series of adaptive host-guest materials derived from dibenzo-heterocyclic analogues, showing host-dependent color-tunable phosphorescence with phosphorescence efficiency of up to 98.9%. The adaptive structural deformation of the guests arises from the hyperconjugation, namely the n→π* interaction, enabling them to inhabit the cavity of host crystals in synergy with steric effects. Consequently, a perfect conformation match between host and guest molecules facilitates the suppression of triplet exciton dissipation, thereby boosting the phosphorescence of these adaptive materials. Moreover, we extend this strategy to a ternary host-guest system, yielding both excitation- and time-dependent phosphorescence with a phosphorescence efficiency of 92.0%. This principle provides a concise way for obtaining efficient and color-tunable phosphorescence, making a major step toward potential applications in optoelectronics., (© 2024. The Author(s).)

Published

2024

3. Abnormal thermally-stimulated dynamic organic phosphorescence.

Author

Wang H, Ma H, Gan N, Qin K, Song Z, Lv A, Wang K, Ye W, Yao X, Zhou C, Wang X, Zhou Z, Yang S, Yang L, Bo C, Shi H, Huo F, Li G, Huang W, and An Z

Abstract

Dynamic luminescence behavior by external stimuli, such as light, thermal field, electricity, mechanical force, etc., endows the materials with great promise in optoelectronic applications. Upon thermal stimulus, the emission is inevitably quenched due to intensive non-radiative transition, especially for phosphorescence at high temperature. Herein, we report an abnormal thermally-stimulated phosphorescence behavior in a series of organic phosphors. As temperature changes from 198 to 343 K, the phosphorescence at around 479 nm gradually enhances for the model phosphor, of which the phosphorescent colors are tuned from yellow to cyan-blue. Furthermore, we demonstrate the potential applications of such dynamic emission for smart dyes and colorful afterglow displays. Our results would initiate the exploration of dynamic high-temperature phosphorescence for applications in smart optoelectronics. This finding not only contributes to an in-depth understanding of the thermally-stimulated phosphorescence, but also paves the way toward the development of smart materials for applications in optoelectronics., (© 2024. The Author(s).)

Published

2024

4. Organic phosphorescent nanoscintillator for low-dose X-ray-induced photodynamic therapy.

Author

Wang X, Sun W, Shi H, Ma H, Niu G, Li Y, Zhi J, Yao X, Song Z, Chen L, Li S, Yang G, Zhou Z, He Y, Qu S, Wu M, Zhao Z, Yin C, Lin C, Gao J, Li Q, Zhen X, Li L, Chen X, Liu X, An Z, Chen H, and Huang W

Subjects

Photosensitizing Agents pharmacology, Radiography, Singlet Oxygen, X-Rays, Photochemotherapy methods

Abstract

X-ray-induced photodynamic therapy utilizes penetrating X-rays to activate reactive oxygen species in deep tissues for cancer treatment, which combines the advantages of photodynamic therapy and radiotherapy. Conventional therapy usually requires heavy-metal-containing inorganic scintillators and organic photosensitizers to generate singlet oxygen. Here, we report a more convenient strategy for X-ray-induced photodynamic therapy based on a class of organic phosphorescence nanoscintillators, that act in a dual capacity as scintillators and photosensitizers. The resulting low dose of 0.4 Gy and negligible adverse effects demonstrate the great potential for the treatment of deep tumours. These findings provide an optional route that leverages the optical properties of purely organic scintillators for deep-tissue photodynamic therapy. Furthermore, these organic nanoscintillators offer an opportunity to expand applications in the fields of biomaterials and nanobiotechnology., (© 2022. The Author(s).)

Published

2022

5. Ultralong organic phosphorescence from isolated molecules with repulsive interactions for multifunctional applications.

Author

Yao X, Ma H, Wang X, Wang H, Wang Q, Zou X, Song Z, Jia W, Li Y, Mao Y, Singh M, Ye W, Liang J, Zhang Y, Liu Z, He Y, Li J, Zhou Z, Zhao Z, Zhang Y, Niu G, Yin C, Zhang S, Shi H, Huang W, and An Z

Abstract

Intermolecular interactions, including attractive and repulsive interactions, play a vital role in manipulating functionalization of the materials from micro to macro dimensions. Despite great success in generation of ultralong organic phosphorescence (UOP) by suppressing non-radiative transitions through attractive interactions recently, there is still no consideration of repulsive interactions on UOP. Herein, we proposed a feasible approach by introducing carboxyl groups into organic phosphors, enabling formation of the intense repulsive interactions between the isolated molecules and the matrix in rigid environment. Our experimental results show a phosphor with a record lifetime and quantum efficiency up to 3.16 s and 50.0% simultaneously in film under ambient conditions. Considering the multiple functions of the flexible films, the potential applications in anti-counterfeiting, afterglow display and visual frequency indicators were demonstrated. This finding not only outlines a fundamental principle to achieve bright organic phosphorescence in film, but also expands the potential applications of UOP materials., (© 2022. The Author(s).)

Published

2022

6. Confining isolated chromophores for highly efficient blue phosphorescence.

Author

Ye W, Ma H, Shi H, Wang H, Lv A, Bian L, Zhang M, Ma C, Ling K, Gu M, Mao Y, Yao X, Gao C, Shen K, Jia W, Zhi J, Cai S, Song Z, Li J, Zhang Y, Lu S, Liu K, Dong C, Wang Q, Zhou Y, Yao W, Zhang Y, Zhang H, Zhang Z, Hang X, An Z, Liu X, and Huang W

Subjects

Molecular Conformation

Abstract

High-efficiency blue phosphorescence emission is essential for organic optoelectronic applications. However, synthesizing heavy-atom-free organic systems having high triplet energy levels and suppressed non-radiative transitions-key requirements for efficient blue phosphorescence-has proved difficult. Here we demonstrate a simple chemical strategy for achieving high-performance blue phosphors, based on confining isolated chromophores in ionic crystals. Formation of high-density ionic bonds between the cations of ionic crystals and the carboxylic acid groups of the chromophores leads to a segregated molecular arrangement with negligible inter-chromophore interactions. We show that tunable phosphorescence from blue to deep blue with a maximum phosphorescence efficiency of 96.5% can be achieved by varying the charged chromophores and their counterions. Moreover, these phosphorescent materials enable rapid, high-throughput data encryption, fingerprint identification and afterglow display. This work will facilitate the design of high-efficiency blue organic phosphors and extend the domain of organic phosphorescence to new applications., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2021