ScholarWorks@동국대학교

초록

Wearable electronic devices demand monolithic solar rechargeable batteries that directly convert photon energy into electricity. Solar rechargeable batteries consist of an active material with electron-hole separation and energy storage ability. In an aqueous zinc-ion battery, a staggered p -n junction comprising n-type fullerene plasma-induced carbon clusters (FPC) and p-type polyaniline (PANI) is employed for a photoelectrode active material. The FPC material acts as an electron transfer layer to block the recombination of photoexcited electrons and holes generated in PANI under illumination. We fabricated an FPC-PANI-based solar battery that exhibited photo-enhanced capabilities of 300 % at a high C-rate, with a high capacity of 310 mAh g-1 and a capacity retention of 91.3 % for 2000 cycles upon light irradiation. After illumination for 10 h, the synergy between the photocathode and photoanode in the fiber-shaped configuration resulted in a record-high photon energy conversion efficiency of 1.15 %, with high-flexibility performances as a wearable device.

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