Abstract
In this study, a material-driven strategy is presented to realize tunable triboelectric-electromagnetic hybrid generators while overcoming the form-factor limitations of conventional magnet-assisted systems. A magneto-dielectric hybrid generator (MDHG) was constructed using a soft magnetized dielectric composite, where NdFeB microparticles were embedded in an Ecoflex matrix and activated by pulse magnetization, allowing a single compliant layer to operate simultaneously as a triboelectric contact medium and a magnetic flux source coupled to a coil. The magnetic filler loading was systematically optimized to elucidate the trade-off between enhanced electromagnetic induction and a non-monotonic triboelectric response governed by dielectric polarization, surface potential, and interfacial energetics. To selectively strengthen the triboelectric branch without sacrificing electromagnetic output, nanoscale BaTiO(3) was introduced as an interstitial dielectric phase to promote polarization-active pathways and suppress screening-driven charge-utilization loss. Under contact-separation operation, the optimized MDHG produced triboelectric outputs up to a V(OC) of 400.40 V and I(SC) of 56.95 μA, while the electromagnetic branch delivered up to a V(OC) of 260.04 mV and I(SC) of 0.89 mA, corresponding to 2.87- and 2.62-fold increases in triboelectric V(OC) and I(SC) over pristine Ecoflex. Finally, the hybrid signatures enabled a wearable smart-skin interface capable of decoupling touch occurrence, intensity, and counter-material identity.