期刊
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY
卷 145, 期 6, 页码 3763-3773出版社
AMER CHEMICAL SOC
DOI: 10.1021/jacs.2c13264
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We propose a facile strategy to achieve room-temperature phosphorescence in conventional hydrogels by polymerization-induced crystallization of dopant molecules, leading to clusterization-induced phosphorescence. Crown ethers dissolved in a concentrated acrylamide aqueous solution crystallize during polymerization to form large spherulites in the hydrogel, resulting in carbonyl clusters and phosphorescence emission. This strategy is universally applicable to hydrogels with different polymeric matrices and dopant molecules. The development of hydrogels with mechanical and phosphorescent properties holds great potential in the biomedical and engineering fields.
Conventional hydrogels such as polyacrylamide and polyacrylic acid ones seldom exhibit phosphorescences at ambient conditions, which limit their applications as optical materials. We propose and demonstrate here a facile strategy to afford these hydrogels with room-temperature phosphorescence by polymerization-induced crystallization of dopant molecules that results in segregation and confinement of the gel matrix with carbonyl groups and thus clusterization-induced phosphorescence. As a model system, crown ethers (CEs) are dissolved in an aqueous solution of concentrated acrylamide that greatly increases the solubility of CEs. During the polymerization process, CEs crystallize to form large spherulites in the polyacrylamide hydrogel. The crystallization arises from the drastically reduced solubility of CEs after the conversion of monomers to polymers during the gel synthesis. The resultant composite hydrogel with a water content of 67 wt % exhibits extraordinary phosphorescence behavior yet maintains good stretchability and resilience. We found that the partial gel matrix is squeezed and confined by in situ-formed crystals, leading to carbonyl clusters and thus phosphorescence emission. The composite gel shows green phosphorescence with an emission peak at 512 nm and a lifetime of 342 ms. The afterglow emission is detectable by the naked eye for several seconds. This strategy has good universality, as validated in other hydrogels with different polymeric matrices and dopant molecules. The development of hydrogels with good mechanical and phosphorescent properties should merit the design of multifunctional soft machines with applications in biomedical and engineering fields.
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