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Achieving Self‐Reinforcing Triboelectric‐Electromagnetic Hybrid Nanogenerator by Magnetocaloric and Magnetization Effects of Gadolinium

Shaokun Gong, Xingwei Wang, B.Z. Tang, Ziyang Xiong, Song Qi, Jie Chen, Peng Yu, Hengyu Guo

2024Advanced Materials23 citationsDOI

Abstract

Triboelectric-electromagnetic hybrid nanogenerator (TEHG) has emerged as a promising technology for distributed energy harvesting. However, currently reported hybrid generators are straightforward combinations of two functional components. Moreover, inevitable heat from friction intensifies material abrasion and degrades the performance of polymer-based triboelectric nanogenerators (TENGs). Here, a self-reinforcing TEHG (SR-TEHG) that harnesses the magnetocaloric and magnetization effects of gadolinium (Gd), is proposed. The synergy between TENG and electromagnetic generator (EMG) renders them an indivisible unit. Leveraging Gd's magnetocaloric effect, an efficient heat transfer mechanism is constructed to cool the tribolayer and strengthen the device's electrical stability. After 80 h of continuous operation, the optimized TENG occupies a charge decay rate of only 0.32% per hour, significantly outperforming most existing TENGs. Additionally, Gd's magnetization effect boosts the power of EMG by ≈80.84%. This work provides a universal solution in hybrid generators where internal components reinforce each other, achieving a synergistic effect of 1 + 1 > 2.

Topics & Concepts

Triboelectric effectMaterials scienceMagnetic refrigerationNanogeneratorMagnetizationGadoliniumComposite materialNanotechnologyCondensed matter physicsMagnetic fieldMetallurgyPhysicsPiezoelectricityQuantum mechanicsAdvanced Sensor and Energy Harvesting MaterialsSupercapacitor Materials and FabricationElectromagnetic wave absorption materials
Achieving Self‐Reinforcing Triboelectric‐Electromagnetic Hybrid Nanogenerator by Magnetocaloric and Magnetization Effects of Gadolinium | Litcius