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Engineering liquid crystal elastomer unlocks high thermopower for fiber-shaped ionic thermoelectric capacitors

Liuqi Cao, Tingting Sun, Huiru Zhao, Lianjun Wang, Wan Jiang

2025Nature Communications5 citationsDOIOpen Access PDF

Abstract

Ionic thermoelectric (i-TE) have become promising candidate for harvesting low-grade thermal energy. However, the development of n-type i-TE materials still lag far behind their p-type counterparts, which impedes the application. Herein, engineering a liquid crystal elastomer (LCE) from side-chain to main-chain structure, just swollen with single LiBF4 or EMIM TFSI, enables the largest adjustable p-n (28.8 ~ −27.4 mV K−1) span among current homologous materials below 30% RH. These high n- and p-type performance further ensure the successful integration of a homogeneous π-type fiber-shaped i-TE capacitor, where three p/n pairs yield an output voltage of 402.5 mV under a tiny temperature difference of 2.5 K. The areal energy density of per n-type fiber reaches 8.1 mJ m−2. More importantly, the i-TE materials also exhibit excellent stability under loadings of cyclic stretching, long-term testing, or temperature-controlled cycling, highlighting its potential for efficient thermal-charge energy storage in flexible electronics and smart wearables. Ionic thermoelectric materials are promising for harvesting energy, but n-type materials are not as efficient as p-type materials. Here the authors report a homologous n-/p-type thermoelectric material using a liquid crystal elastomer network for energy harvesting.

Topics & Concepts

Materials scienceThermoelectric effectElastomerCapacitorIonic liquidElectronicsEnergy storageThermal stabilityVoltageComposite materialSeebeck coefficientCrystal (programming language)Flexible electronicsLiquid crystalOptoelectronicsThermoelectric materialsHomogeneousThermalSupercapacitorIonic bondingEnergy densityYield (engineering)Thermal conductivityEngineering physicsPolymerEnergy harvestingSpan (engineering)PeekThermal expansionThermal fluctuationsThermoelectric coolingIonic conductivityHigh voltageFiberThermal energyNanotechnologyAdvanced Sensor and Energy Harvesting MaterialsDielectric materials and actuatorsAdvanced Materials and Mechanics
Engineering liquid crystal elastomer unlocks high thermopower for fiber-shaped ionic thermoelectric capacitors | Litcius