Litcius/Paper detail

Wearable Ultrahigh Current Power Source Based on Giant Magnetoelastic Effect in Soft Elastomer System

Guorui Chen, Yihao Zhou, Yunsheng Fang, Xun Zhao, Sophia Shen, Trinny Tat, Ardo Nashalian, Jun Chen

2021ACS Nano91 citationsDOI

Abstract

In this study, we present the observation of the giant magnetoelastic effect that occurs in soft elastomer systems without the need of external magnetic fields and possesses a magnetomechanical coupling factor that is four times larger than that of traditional rigid metal-based ferromagnetic materials. To investigate the fundamental scientific principles at play, we built a linear model by using COMSOL Multiphysics, which was consistent with the experimental observations. Next, by combining the giant magnetoelastic effect with electromagnetic induction, we developed a magnetoelastic generator (MEG) for biomechanical energy conversion. The wearable MEG demonstrates an ultrahigh output current of 97.17 mA, a low internal impedance of around ∼40 Ω, and an intrinsic waterproof property. We further leveraged the wearable MEG as an ultrahigh current power source to drive a Joule-heating textile for personalized thermoregulation, which increased the temperature of the fiber-shaped resistor by 0.2 °C. The development of the wearable MEG will act as an alternative and compelling approach for on-body electricity generation and arouse a wide range of possibilities in the renewable energy community.

Topics & Concepts

MultiphysicsWearable computerMaterials scienceResistorPEDOT:PSSGenerator (circuit theory)Mechanical engineeringMagnetostrictionAcousticsPower (physics)Electrical engineeringComputer sciencePhysicsMagnetic fieldComposite materialFinite element methodEngineeringPolymerVoltageEmbedded systemThermodynamicsQuantum mechanicsAdvanced Sensor and Energy Harvesting MaterialsInnovative Energy Harvesting TechnologiesVibration Control and Rheological Fluids