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High-Curie-Temperature Elastic Polymer Ferroelectric by Carbene Cross-Linking

Linping Wang, Liang Gao, Bowen Li, Bing Hu, Bing Hu, Tianhua Xu, Huang Lin, Ren Zhu, Ben-Lin Hu, Ben-Lin Hu, Run‐Wei Li

2024Journal of the American Chemical Society29 citationsDOI

Abstract

With the emergence of wearable electronics, ferroelectrics are poised to serve as key components for numerous potential applications. Currently, intrinsically elastic ferroelectrics featuring a network structure through a precise "slight cross-linking" approach have been realized. The resulting elastic ferroelectrics demonstrate a combination of stable ferroelectric properties and remarkable resilience under various strains. However, challenges arose as the cross-linking temperature was too high when integrating ferroelectrics with other functional materials, and the Curie temperature of this elastic ferroelectric was comparatively low. Addressing these challenges, we strategically chose a poly(vinylidene fluoride)-based copolymer with high vinylidene fluoride content to obtain a high Curie temperature while synthesizing a cross-linker with carbene intermediate for high reactivity to reduce the cross-linking temperature. At a relatively low temperature, we successfully fabricated elastic ferroelectrics through carbene cross-linking. The resulting elastic polymer ferroelectrics exhibit a higher Curie temperature and show a stable ferroelectric response under strains up to 50%. These materials hold significant potential for integration into wearable electronics.

Topics & Concepts

Curie temperatureFerroelectricityChemistryFerroelectric polymersPolymerPiezoelectricityCondensed matter physicsNanotechnologyMaterials scienceComposite materialOptoelectronicsFerromagnetismPhysicsDielectricAdvanced Sensor and Energy Harvesting MaterialsFerroelectric and Piezoelectric MaterialsDielectric materials and actuators
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