Photoassisted Li-ion de-intercalation and Ni? plus valence conversion win-win boost energy storage performance in Ni/CdS@Ni3S2-based Li-ion battery

The development of bifunctional electrode with photoactivity and lithium storage properties is critical for manufacturing high-efficiency solar energy conversion/storage integrated devices. Herein, for the first time, Ni foam supported Ni3S2 nanosheets covered CdS photocatalyst, a core-shell heterojunction nanorods array (Ni/ CdS@Ni3S2), is employed as photoelectrode for photo-assisted lithium-ion batteries (PA-LIBs). The assembled PA-LIBs can be off-grid charged by net solar light and on-grid photoassisted charged/discharged, respectively. Without external bias voltage, the overall solar-to-electrical energy conversion efficiency reaches 0.11 %. In addition, during the photo-assisted charging/discharging processes, the solar to electricity energy conversion efficiency is increased to 3.5 % and 2.1 %, respectively, and the total special capacity of such photocell is significantly improved by 13.7 % and 15.9 % compared with its conventional electric energy charging/dis-charging battery. Impressively, the PA-LIB maintains good photo-responsive activity even after about 250 charge/discharge cycles. Mechanism investigation reveals that photo-assisted Li-ion de-intercalation and Ni delta+ valence conversion together boosts the lithium-ion storage reaction more completely, thus improving the energy storage performance of Ni/CdS@Ni3S2-based Li-ion battery.

Automated summary

The development of a bifunctional electrode with photoactivity and lithium storage properties is crucial for efficient solar energy conversion and storage. In this study, a Ni foam supported Ni3S2 nanosheets covered CdS photocatalyst, known as a core-shell heterojunction nanorods array (Ni/ CdS@Ni3S2), is used as a photoelectrode for photo-assisted lithium-ion batteries. The assembled batteries can be charged off-grid by solar light and on-grid through photo-assisted charged/discharged. The overall solar-to-electrical energy conversion efficiency reaches 0.11% without external bias voltage, and it increases to 3.5% and 2.1% during photo-assisted charging and discharging processes, respectively, compared to conventional electric energy batteries.