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Cellulose-Based Ultralong Room-Temperature Phosphorescence Nanomaterials with Tunable Color and High Quantum Yield via Nano-Surface Confining Effect

Xin Zhang, Chunchun Yin, Jingxuan You, Ruiqiao Li, Jinming Zhang, Jinming Zhang, Yaohui Cheng, Yirong Wang, Jun Zhang, Jun Zhang

2023Research32 citationsDOIOpen Access PDF

Abstract

How to achieve multicolor organic room-temperature phosphorescence (RTP) is still challenging and striking. Herein, we discovered a new principle to construct eco-friendly color-tunable RTP nanomaterials based on the nano-surface confining effect. Cellulose nanocrystal (CNC) immobilized cellulose derivatives (CX) containing aromatic substituents via hydrogen-bonding interactions, which effectively inhibit the motion of cellulose chains and luminescent groups to suppress the nonradiative transitions. Meanwhile, CNC with a strong hydrogen-bonding network can isolate oxygen. CX with different aromatic substituents regulate the phosphorescent emission. After mixing CNC and CX directly, a series of polychromatic ultralong RTP nanomaterials were obtained. The RTP emission of the resultant CX@CNC can be finely adjusted through the introduction of various CX and the regulation of the CX/CNC ratio. Such a universal, facile, and effective strategy can be used to fabricate various colorful RTP materials with wide color gamut. Because of the complete biodegradability of cellulose, the multicolor phosphorescent CX@CNC nanomaterials can be used as eco-friendly security inks to fabricate disposable anticounterfeiting labels and information-storage patterns via conventional printing and writing processes.

Topics & Concepts

PhosphorescenceNanomaterialsCelluloseMaterials scienceNano-Quantum yieldNanocrystalNanotechnologyChemical engineeringComposite materialFluorescenceOpticsEngineeringPhysicsLuminescence and Fluorescent MaterialsCarbon and Quantum Dots ApplicationsAdvanced Sensor and Energy Harvesting Materials
Cellulose-Based Ultralong Room-Temperature Phosphorescence Nanomaterials with Tunable Color and High Quantum Yield via Nano-Surface Confining Effect | Litcius