Simple Vanilla Derivatives for Long-Lived Room-Temperature Polymer Phosphorescence as Invisible Security Inks.
Yongfeng ZhangZhonghao WangYan SuYan ZhengWenji TangChaolong YangHailong TangLunjun QuYoubing LiRongjun ZhaoPublished in: Research (Washington, D.C.) (2021)
Developing novel long-lived room-temperature polymer phosphorescence (RTPP) materials could significantly expand their application scope. Herein, a series of RTPP materials based on eight simple vanilla derivatives for security ink application are reported. Attributed to strong mutual hydrogen bonding with polyvinyl alcohol (PVA) matrix, vanilla-doped PVA films exhibit ultralong phosphorescence emission under ambient conditions observed by naked eyes, where methyl vanillate shows the longest emission time up to 7 s. Impressively, when vanilla-doped PVA materials are utilized as invisible security inks, and the inks not only present excellent luminescent emission stability under ambient conditions but also maintain perfect reversibility between room temperature and 65°C for multiple cycles. Owing to the unique RTPP performance, an advanced anticounterfeiting data encoding/reading strategy based on handwriting technology and complex pattern steganography is developed.
Keyphrases
- room temperature
- quantum dots
- air pollution
- global health
- particulate matter
- ionic liquid
- metal organic framework
- highly efficient
- sensitive detection
- optical coherence tomography
- public health
- electronic health record
- visible light
- machine learning
- deep learning
- artificial intelligence
- data analysis
- cataract surgery
- light emitting