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Isomerism-enabling low-temperature ultrasensitive and moisture-resistant fire-alarming "Guarder" via color changing.
- Source :
-
Polymer Degradation & Stability . Jul2024, Vol. 225, pN.PAG-N.PAG. 1p. - Publication Year :
- 2024
-
Abstract
- • Quasi-core-shell APP vertically deposited by thermochromic Salen lamellas was bioinspired designed. • MAPP@Salen disclosed an unprecedentedly low triggering temperature of 120 °C and time of 1 s. • An isomerization of Salen to cis-keto and vertically alignment accounted for ultra-sensitiveness. • Model coating with MAPP@Salen presented a 0.3 s responsive time at 250 oC and remote monitoring. • Fire-alarming coating possessed an improved fire protection and moisture resistance. Aiming to integrate a low-temperature, ultrasensitive and wireless remote-monitoring fire alarming with a fire suppression into a commercialized system, in view of a heat-induced tailored isomerization of Salen molecules and sunflower configuration for a heat capturing, we constructed a quasi-core-shell MAPP@Salen with silaned ammonia polyphosphate guiding a vertical deposition of Salen lamellas assembly. Resultantly, MAPP@Salen demonstrated an ultralow triggering temperature of 120 °C and 1 s time at 250 oC with a remarkable color from yellow to dark red. A Salen isomerization and its vertical alignment on MAPP accounted for an ultra-sensitiveness feature. A model acrylic coating with MAPP@Salen presented a 0.3 s responsive time at 250 °C as well as instant (0.5 s) and unstopped warning once flame approached. A wireless signal communication system via a color recognition algorithm and 4 G IoT was realized. Additionally, the coating provided >10 min and ultrastrong intumescent fire protection via a Salen-participative charring optimization as well as well-persevered structural integrity after a long-term water attack. The fire-alarming capability was retained as well. This work pertaining to a bio-inspired hierarchical assembly integrates a low-temperature ultra-sensitive fire alarming and an optimized fire resistance for commercial all-time-scale fire retardants in multi-scenario universal applications. [Display omitted] [ABSTRACT FROM AUTHOR]
Details
- Language :
- English
- ISSN :
- 01413910
- Volume :
- 225
- Database :
- Academic Search Index
- Journal :
- Polymer Degradation & Stability
- Publication Type :
- Academic Journal
- Accession number :
- 177601259
- Full Text :
- https://doi.org/10.1016/j.polymdegradstab.2024.110831