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Thermodynamically Driven Phase Separation for Wearable Ionic Thermoelectrics

Junjian Zheng, Zixian Dong, Senpeng Jiang, Yu Lin Hu, Rui Gao, Yaru Yue, Sangjin Yang, Xin Fan, Feng Li, Yujie Zheng, Kuan Sun, Changduk Yang, Shanshan Chen

2025Advanced Functional Materials5 citationsDOIOpen Access PDF

Abstract

Abstract The integration of high thermoelectric performance, mechanical compliance, and self‐healing capability in ionic conductors remains a fundamental challenge for wearable energy technologies. Here, these limitations are overcome through the thermodynamic design of phase‐separated ionic gels. By precisely modulating the interactions between the in situ polymerizable hydrophilic matrix (PDAC) (Poly([2‐(Acryloyloxy)ethyl]dimethylammonium chloride)) and the hydrophobic ionic liquid (EMIM:TFSI) (1‐ethyl‐3‐methylimidazolium bis(trifluoromethanesulfonyl)imide), spontaneous formation of bicontinuous microstructures is achieved that simultaneously deliver record‐high thermopower (30.80 mV K −1 ), exceptional mechanical properties (762% strain, 2862.51 kJ m −3 toughness), and self‐healing efficiency (85% thermal voltage retention). The microstructure emerges from balanced enthalpic‐entropic contributions as predicted by Flory‐Huggins theory, creating percolated ion‐selective transport channels within a deformable polymer skeleton while maintaining interfacial stability. This approach overcomes the long‐standing trade‐offs among ionic thermophoresis, mechanical robustness, and reparability in conventional ionic thermoelectrics. As a demonstration, 3D‐printed stretchable thermoelectric wristbands with outstanding energy‐harvesting performance are fabricated. The work establishes a paradigm for multifunctional ionic materials, with immediate applications in wearable thermal energy harvesting and adaptive sensors, while providing a framework for next‐generation soft electronics.

Topics & Concepts

Materials scienceIonic bondingThermoelectric effectIonic liquidThermoelectric materialsMechanical energyNanotechnologyMicrostructureWork (physics)Phase (matter)PolymerThermalSeebeck coefficientEnergy harvestingWearable computerThermal energyChemical physicsElectrical conductorIonic conductivityWearable technologySoft materialsIonThermoelectric generatorPhase transitionThermal fluctuationsBioelectronicsVoltageEnergy storageOptoelectronicsAdvanced Sensor and Energy Harvesting MaterialsAdvanced Thermoelectric Materials and DevicesDielectric materials and actuators
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