Facile Preparation of Full‐Color Tunable Room Temperature Phosphorescence Cellulose via Click Chemistry

Gao, Qian; Shi, Meichao; Chen, Mingxing; Hao, Xiang; Chen, Gegu; Bian, Jing; Lü, Baozhong; Ren, Junli; Peng, Feng

doi:10.1002/smll.202309131

Cited by 10 publications

(1 citation statement)

References 55 publications

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“…The principal emissive species in arylboronic acids-KGM are the arylboronic acid chromophores. [57] The disparities between the lowest unoccupied molecular orbital (LUMO) and highest occupied molecular orbital (HOMO) gaps align with the optical gaps. The HOMO-LUMO gaps of BpB, PheB, and PyB are 5.64, 4.93, and 4.01 eV, respectively (Figure 4c).…”

Section: Mechanism Of the Afterglow Rtp In Arylboronic Acids-kgmmentioning

confidence: 90%

3D Printed Room Temperature Phosphorescence Materials Enabled by Edible Natural Konjac Glucomannan

Wu,

Li,

Chen

et al. 2024

Advanced Materials

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Shaping room temperature phosphorescence (RTP) materials into three‐dimensional (3D) bodies is important for stereoscopic optoelectronic displays, but remains challenging due to their poor processability and mechanical properties. Here, konjac glucomannan is employed to anchor arylboronic acids with various π conjugations via a facile B─O covalent reaction to afford printable inks, using which full‐color high‐fidelity 3D RTP objects with high mechanical strength can be obtained via direct ink writing‐based 3D printing and freeze‐drying. The doubly rigid structure supplied by the synergy of hydrogen bonding and B─O covalent bonding can protect the triplet excitons, thus the prepared 3D RTP object shows a striking lifetime of 2.14 s. The printed counterparts are successfully used for 3D anti‐counterfeiting and can be recycled and reprinted nondestructively by dissolving in water. This success expands the scope of printable 3D luminescent materials, providing an eco‐friendly platform for the additive manufacturing of sophisticated 3D RTP architectures.This article is protected by copyright. All rights reserved

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Section: Mechanism Of the Afterglow Rtp In Arylboronic Acids-kgmmentioning

confidence: 90%

3D Printed Room Temperature Phosphorescence Materials Enabled by Edible Natural Konjac Glucomannan

Wu,

Li,

Chen

et al. 2024

Advanced Materials

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One‐Step Fabrication of New PCPNs with Unique Optical Responses for Ultra‐Stable Anti‐Counterfeiting Labels

Chen,

Wu,

Tian

et al. 2024

Adv Funct Materials

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Constructing a library of stable phosphors with unconventional fluorescence (FL) and room temperature phosphorescence (RTP) color combination is an effective approach to enhance anti‐counterfeiting strength, but remains a challenge. Herein, a one‐step strategy is proposed to fabricate ultra‐stable CsPbX3/carbon dots (CDs) @NH4AlP2O7 (X = Cl, Br, and I) nanocomposites (PCPNs) with full‐spectrum FL emission and constant short‐wavelength blue RTP emission, breaking the conventional luminescent properties that RTP generally exhibit obvious wavelength red‐shifts compared with FL. The enhanced full‐color (457–612 nm) FL emissions are implemented by adjusting halogen compositions, which is attributed to CsPbX3 as the dominant FL center. Owing to the RTP emission of CDs, constant long‐lived blue RTP emission lasting 12 s is observed from PCPNs. Additionally, the PCPNs exhibit remarkable tolerance to prolonged ultraviolet irradiation and erosion by solutions with various pH and solvents, supported by NH4AlP2O7 inert shell stabilizing the perovskite structure and triplet state. When the anti‐counterfeiting ink based on PCPNs is printed on various substrates, fine anti‐counterfeiting labels with unconventional emission combinations of FL and RTP are formed and show excellent solvent resistance and mechanical stability. This study provides fresh perspectives on the development of anti‐counterfeiting labels with enhanced security strength and long‐term effects.

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Fully Exploiting Clusterization‐Triggered Room Temperature Phosphorescence of Cellulose by Stepwise Rigidification for Long‐Lived and Excitation Wavelength‐Dependent Afterglows

Gao,

Shi,

Rao

et al. 2024

Adv Funct Materials

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Achieving long‐lived room temperature phosphorescence (RTP) in nonconventional luminophores devoid of any conjugated units is fascinating but remains formidably challenging due to their low intersystem crossing efficiency and strong nonradiative decay. Herein, a stepwise rigidification strategy is developed to suppress the nonradiative decay and fully exploit the clusterization‐triggered RTP performance of cellulose. Specifically, the crystallinity is enhanced, and hydrogen bonding is reconstructed by a directed oxidation‐reduction reaction to afford a more rigid environment of cellulose; then, the reconstructed cellulose is further cross‐linked by boric acid to activate double confinement architecture. In return, the phosphorescence lifetime of the target cellulose increases almost one order of magnitude, and the phosphorescence quantum yield increases more than 27 folds. Moreover, the afterglow of the RTP cellulose can be regulated from blue to green by changing excitation wavelength, which is useful for advanced information encryption and anti‐counterfeiting. The stepwise rigidification strategy is also applicable for preparing other nature polysaccharides‐based long‐lived RTP materials, such as chitosan and sodium alginate. Nature polysaccharides are completely biodegradable; thus, this work paves the way for the development of eco‐friendly and practical color‐variable RTP materials.

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Facile Preparation of Full‐Color Tunable Room Temperature Phosphorescence Cellulose via Click Chemistry

Cited by 10 publications

References 55 publications

3D Printed Room Temperature Phosphorescence Materials Enabled by Edible Natural Konjac Glucomannan

3D Printed Room Temperature Phosphorescence Materials Enabled by Edible Natural Konjac Glucomannan

One‐Step Fabrication of New PCPNs with Unique Optical Responses for Ultra‐Stable Anti‐Counterfeiting Labels

Fully Exploiting Clusterization‐Triggered Room Temperature Phosphorescence of Cellulose by Stepwise Rigidification for Long‐Lived and Excitation Wavelength‐Dependent Afterglows

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