Human-motion interactive energy harvester based on polyaniline functionalized textile fibers following metal/polymer mechano-responsive charge transfer mechanism

Abstract Our experimental outturn opens up a new vision by proposing mechano-responsive charge transfer mechanism (MRCTM) to π-conjugated polymers in the field of human-motion interactive energy harvester. Doped polyaniline ( d -PANi) has been used to functionalize conducting textile fibers ( f -CTFs) and integrated with our proposed design for wearable power plant. Each f -CTF generates current by patting, bending, or even soft touching. Localized force deformation at the metal/polymeric interface layer with direct visualization of charge distribution pattern has been extensively studied by atomic force microscopy. The integrated arrays of f -CTFs produce a peak power-density of ∼0.6 W m −2 with output current-density of ∼22 mA m −2 and can power at least 10 white LEDs of 2.5 W. The procured energy from f -CTFs is capable of charging a commercial 10 μF capacitor to 3 V in 80 s and powering portable electronic devices. The prototype energy harvester stably shows the same performance after more than 100 thousand times of patting, bending or twisting.