Litcius/Paper detail

Moisture-induced autonomous surface potential oscillations for energy harvesting

Yu Long, Peisheng He, Zhichun Shao, Zhaoyang Li, Han Kim, Archie Mingze Yao, Yande Peng, Renxiao Xu, Christine Heera Ahn, Seung‐Wuk Lee, Junwen Zhong, Liwei Lin

2021Nature Communications57 citationsDOIOpen Access PDF

Abstract

Abstract A variety of autonomous oscillations in nature such as heartbeats and some biochemical reactions have been widely studied and utilized for applications in the fields of bioscience and engineering. Here, we report a unique phenomenon of moisture-induced electrical potential oscillations on polymers, poly([2-(methacryloyloxy)ethyl] dimethyl-(3-sulfopropyl) ammonium hydroxide-co-acrylic acid), during the diffusion of water molecules. Chemical reactions are modeled by kinetic simulations while system dynamic equations and the stability matrix are analyzed to show the chaotic nature of the system which oscillates with hidden attractors to induce the autonomous surface potential oscillation. Using moisture in the ambient environment as the activation source, this self-excited chemoelectrical reaction could have broad influences and usages in surface-reaction based devices and systems. As a proof-of-concept demonstration, an energy harvester is constructed and achieved the continuous energy production for more than 15,000 seconds with an energy density of 16.8 mJ/cm 2 . A 2-Volts output voltage has been produced to power a liquid crystal display toward practical applications with five energy harvesters connected in series.

Topics & Concepts

Oscillation (cell signaling)MoistureActivation energyAmmonium hydroxideChemical physicsKinetic energyMaterials scienceAttractorExcited stateEnergy harvestingNanotechnologyBiological systemChemistryPhysicsPower (physics)ThermodynamicsAtomic physicsPhysical chemistryOrganic chemistryClassical mechanicsComposite materialMathematical analysisBiologyMathematicsBiochemistryAdvanced Sensor and Energy Harvesting MaterialsElectrowetting and Microfluidic TechnologiesNonlinear Dynamics and Pattern Formation