Excitation‐Dependent Long Afterglow Room‐Temperature Phosphorescence Material Activated by Doping Boric Acid Matrix

Deng, Jun-jie; Guan, Zhihao; Fu, Donglei; Zheng, Yuewei; Chen, Zhengjie; Li, Houbin; Liu, Xinghai

doi:10.1002/adom.202300207

Cited by 13 publications

(10 citation statements)

References 55 publications

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“…As shown in Figure d, heated BA and TDCA@BA showed almost identical behavior in the FTIR spectra. Typically, three obvious peaks at 650, 1190, and 1435 cm –1 were observed, corresponding to the vibration of B–O bonds, B–OH bending, and stretching vibrations of B–O, respectively. ,, Two relatively wide peaks at 1490 and 3216 cm –1 are associated with B–O and −OH stretching vibrations, respectively. After loading TDCA, the peak at 3216 cm –1 became wider, suggesting the formation of hydrogen bonds between TDCA and BA matrix. , This is also consistent with the results of the Raman measurements (Figure S1).…”

Section: Resultsmentioning

confidence: 99%

Achieving Efficient Room-Temperature Phosphorescence in the Host–Guest System through Covalent-Bond-Strengthened Hydrogen Bonding

Guo,

Shi,

Shen

et al. 2024

J. Phys. Chem. C

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Achieving high performance room-temperature phosphorescence (RTP) with a clearly understood mechanism is highly desired. In this work, efficient RTP materials with a delayed emission quantum yield of 50% were synthesized through loading thiophenes into the matrix of inorganic boric acid (BA). The RTP mechanisms were clarified through structural, photophysical, and theoretical studies of RTP materials produced by loading a series of thiophenes into a BA matrix. Our study demonstrated the critical role of molecular interactions between BA and thiophenes. Covalent bonds have strengthened the hydrogen bonds to modulate the photophysical properties of thiophenes, which reduced the energy gap between the singlet and triplet states. The RTP color and emission lifetime could be well-tuned by substituting the chemical groups on the skeleton of thiophenes, which endowed their applications with information encryption. These results opened a door for designing efficient RTP materials for various applications as well as a clear mechanism for studying the host−guest systems.

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Section: Resultsmentioning

confidence: 99%

Achieving Efficient Room-Temperature Phosphorescence in the Host–Guest System through Covalent-Bond-Strengthened Hydrogen Bonding

Guo,

Shi,

Shen

et al. 2024

J. Phys. Chem. C

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“…Using blue LED chips with Cr 3+ doped near-infrared phosphors can notably boost near-infrared emission efficiency. 21–23…”

Section: Introductionmentioning

confidence: 99%

Simultaneous NIR photoluminescence and mechanoluminescence from Cr³⁺ activated MgGa₂O₄ phosphors with multifunctions for optical sensing

Wang,

Pan,

Wang

et al. 2024

J. Mater. Chem. C

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“…PMMA and PVA are frequently used as polymer hosts as they can provide a rigid environment to significantly inhibit nonirradiative relaxation of triplet excitons. − Compared with the host, the guest library expands more discretely. Till date, derivatives of 1 H -benzo[f]indole (Bd), , 7 H -Benzo[c]carbazole (BCz), 5 H -Benzo[c]carbazole (BCz-1), , N -phenyl-1-naphthylamine ( N -1), N -phenyl-2-naphthylamine ( N -2), phenylboronic acid, − and so forth have been reported as excellent guests. It is worth mentioning that some guests (such as Bd, BCz, BCz-1, etc.)…”

Section: Introductionmentioning

confidence: 99%

Photo- and Oxygen- Synergistically Controlled Selective Expression of Organic Phosphorescence Units

Jin,

Han,

et al. 2024

ACS Appl. Mater. Interfaces

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Dynamic control of ultralong organic room-temperature phosphorescence (UORTP) is a charming target. Herein, we report a stimuli-responsive phosphorescence unit 7H-indolo[2,3-c]quinoline (NBCz) and its derivatives (PCBNBCz, FSO 2 NBCz, and N 2 BCzSO 2 NBCz) that show photo-and oxygen-synergistically induced afterglow activation and afterglow color change in the PMMA film. PCBNBCz and FSO 2 NBCz feature a donor− acceptor (D−A) structure, and N 2 BCzSO 2 NBCz features acceptor-bridged two different phosphorescence units (NBCz and N 2 BCz). The photoactivated UORTP of PCBNBCz and FSO 2 NBCz arises from the photoinduced consumption of oxygen in the PMMA film. It is clear that the phosphorescence unit NBCz contributes to subsequent photoinduced UORTP color change because the NBCz-doped PMMA film shows the same UORTP color change process. ESR and HRMS measurements confirmed that oxidation of NBCz occurs at the nitrogen atom of the quinoline ring via photogenerated superoxide radicals, which results in the UORTP color change. TDDFT calculations proved that after oxidation of NBCz, the T 1 energy level declines significantly. Furthermore, photocontrolled selective expression of phosphorescence units is achieved in the case of N 2 BCzSO 2 NBCz. After further UV irradiation, oxidation of NBCz happened, and the oxidized form N 2 BCzSO 2 NBCz-O emitted the intrinsic orange UORTP of NBCz-O selectively and screened the intrinsic yellowish-green UORTP of N 2 BCz. Finally, multilevel photolithography can be demonstrated based on the photoactivated UORTP and the photoinduced UORTP color change. This work may give a deep insight into organic phosphorescence and pave a simple way for the development of stimulus-responsive smart UORTP materials.

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Excitation‐Dependent Long Afterglow Room‐Temperature Phosphorescence Material Activated by Doping Boric Acid Matrix

Cited by 13 publications

References 55 publications

Achieving Efficient Room-Temperature Phosphorescence in the Host–Guest System through Covalent-Bond-Strengthened Hydrogen Bonding

Achieving Efficient Room-Temperature Phosphorescence in the Host–Guest System through Covalent-Bond-Strengthened Hydrogen Bonding

Simultaneous NIR photoluminescence and mechanoluminescence from Cr³⁺ activated MgGa₂O₄ phosphors with multifunctions for optical sensing

Photo- and Oxygen- Synergistically Controlled Selective Expression of Organic Phosphorescence Units

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Excitation‐Dependent Long Afterglow Room‐Temperature Phosphorescence Material Activated by Doping Boric Acid Matrix

Cited by 13 publications

References 55 publications

Achieving Efficient Room-Temperature Phosphorescence in the Host–Guest System through Covalent-Bond-Strengthened Hydrogen Bonding

Achieving Efficient Room-Temperature Phosphorescence in the Host–Guest System through Covalent-Bond-Strengthened Hydrogen Bonding

Simultaneous NIR photoluminescence and mechanoluminescence from Cr3+ activated MgGa2O4 phosphors with multifunctions for optical sensing

Photo- and Oxygen- Synergistically Controlled Selective Expression of Organic Phosphorescence Units

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Simultaneous NIR photoluminescence and mechanoluminescence from Cr³⁺ activated MgGa₂O₄ phosphors with multifunctions for optical sensing