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

Yao, Xiaokang; Ma, Huili; Wang, Xiao; Wang, He; Wang, Qian; Zou, Xin; Song, Zhicheng; Jia, Wenyong; Li, Yuxin; Mao, Yufeng; Singh, Manjeet; Ye, Wenpeng; Liang, Jian; Zhang, Yanyun; Liu, Zhuang; He, Yixiao; Li, Jingjie; Zhou, Zixing; Zhao, Zhu; Zhang, Yuan; Niu, Guowei; Yin, Chengzhu; Zhang, Shasha; Shi, Huifang; Huang, Wei; An, Zhongfu

doi:10.1038/s41467-022-32029-1

Cited by 87 publications

(31 citation statements)

References 58 publications

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“…One can see that BI crystals are packed more closely than NMeBI. This point can also be supported by comparing their crystal densities (BI: 1.471 g/cm 3 > NMeBI: 1.347 g/cm 3 ). Therefore, it can be concluded that the rigid environment created by abundant hydrogen bonds and π−π stacking is responsible for the observed pRTP in the doped crystals.…”

mentioning

confidence: 71%

Boosting the Phosphorescence Efficiency in Doped Organic Crystals: Critical Role of Hydrogen Bonding

Liao

Wang

et al. 2023

J. Phys. Chem. Lett.

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Host–guest doping systems with phthalimides (BI) and N-methylphthalimide (NMeBI) as the host and 1,8-naphthalimide (NI) and 4-bromo-1,8-naphthalimide (4BrNI) as the guest have been developed. The 0.2% NI/BI (molar ratio) with a strong C=O···H–N hydrogen bond exhibited a phosphorescence quantum efficiency (29.2%) higher than that of NI/NMeBI with a weak C=O···H–C hydrogen bond (10.1%). A similar trend was observed in the 4BrNI guest system. A remarkable phosphorescent efficiency of 42.1% was achieved in a 0.5% 4BrNI/BI composite, which represents the highest value in NI-based phosphors. This research indicates stronger hydrogen bonding may have a greater contribution in boosting the phosphorescence efficiency.

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mentioning

confidence: 71%

Boosting the Phosphorescence Efficiency in Doped Organic Crystals: Critical Role of Hydrogen Bonding

Liao

Wang

et al. 2023

J. Phys. Chem. Lett.

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“…Additionally, according to El-Sayed’s rule, the magnitude of SOC (and therefore the ISC) can be elevated by promoting the non-bonding characteristic (n) to π–π* transitions. In such a context, different non-covalent interactions such as halogen bonding, intermolecular electronic coupling of π and n moieties, and efficient π–π stacking by H-aggregation have been proposed to promote ISC, leading to efficient RT phosphorescence. − To understand the ISC routes, TD-DFT calculations have been performed in the monomeric and aggregated (dimer, trimer, tetramer, and large cluster) state at the TPPSh-D3BJ/Def2TzVP level of theory. The calculated excited electronic state energy levels are tabulated in Table S1a–f and diagrammatically summarized in Figure a.…”

Section: Resultsmentioning

confidence: 99%

Temperature-Regulated Dual Phosphorescence and Mechanical Strain-Induced Luminescence Modulation in a Plastically Bendable and Twistable Organic Crystal

et al. 2023

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A unique, thermally interchangeable, and tunable dual phosphorescence from a single-component organic crystal of DBC (3,6-dibromo-9-ethyl-9H-carbazole) is described here. Temperature-regulated relative intensities of a triple-channel radiative process, viz., singlet and dual triplets, enabled a nearwhite luminescence in a wide temperature range. Interestingly, the single crystals of DBC can also be plastically bent using external mechanical stress and allow the modulation of phosphorescence. The luminescence was completely singlet-mediated in the monomeric state, while the crystalline solid had three pathways of radiative processes. Strong n−π interactions mediated by noncovalent interactions significantly augment the initially forbidden n−π* transitions, which enabled a strong spin−orbit coupling to obtain large radiative triplet states in the solid state. Trapped higher energy triplets were the significant contributors to the emission at lower temperatures, whereas, at higher temperatures, the lower lying triplets dominated the process. A detailed mechanistic approach to unraveling the findings is summarized in the article.

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“…Intermolecular H-bonding and halogen bonding are the major interactions to inhibit the nonradiative transitions and oxygen quenching of triplet excitons . High-performance host–guest doped materials are expected to be constructed through the emergence of molecular interactions such as ionic bonding, coordination bonding, and hydrophobic interactions. ,, Moreover, novel doped RTP systems with chirality, specific recognizability, or biological targeting can be constructed through the introduction of corresponding functional groups, which will promote the future development of intelligent response RTP materials.…”

Section: Internal Stimulus Rtp Materials With a Third Componentmentioning

confidence: 99%

Stimulus-Responsive Organic Phosphorescence Materials Based on Small Molecular Host–Guest Doped Systems

Lei

Dai

et al. 2023

J. Phys. Chem. Lett.

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Small molecular host−guest doped materials exhibit superiority toward highefficiency room-temperature phosphorescence (RTP) materials due to their structural design diversity and ease of preparation. Dynamic RTP materials display excellent characteristics, such as good reversibility, quick response, and tunable luminescence ability, making them applicable to various cutting-edge technologies. Herein, we summarize the advances in host−guest doped dynamic RTP materials that respond to external and internal stimuli and present some insights into the molecular design strategies and underlying mechanisms. Subsequently, specific viewpoints are described regarding this promising field for the development of dynamic RTP materials. This Perspective is highly beneficial for future intelligent applications of dynamic RTP systems.

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

Cited by 87 publications

References 58 publications

Boosting the Phosphorescence Efficiency in Doped Organic Crystals: Critical Role of Hydrogen Bonding

Boosting the Phosphorescence Efficiency in Doped Organic Crystals: Critical Role of Hydrogen Bonding

Temperature-Regulated Dual Phosphorescence and Mechanical Strain-Induced Luminescence Modulation in a Plastically Bendable and Twistable Organic Crystal

Stimulus-Responsive Organic Phosphorescence Materials Based on Small Molecular Host–Guest Doped Systems

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