Irradiation Spillover Effect in Photo-Assisted Ion Batteries: Overcoming Size Limits for Solar Utilization

Photo-assisted ion batteries demonstrate remarkable potential for portable and decentralized solar energy utilization, due to their profound capacity enhancement under irradiation accompanied by promoted discharge voltages. However, ion batteries in practice are highly compact with limited surface area for irradiation. Overcoming the size limit for irradiation is a challenge. Herein, an irradiation spillover effect in photo-assisted ion batteries is demonstrated, that is the impact of irradiation on the battery is not restrained within the irradiated area but can spillover the whole electrode. This phenomenon is a consequence of the light-induced potential difference between irradiated and unirradiated regions, leading to selective ion insertion. Irradiated regions favored H+ insertion due to light-induced proton-coupled electron transfer, while unirradiated regions preferred Zn2+ insertion. Consequently, the capacity enhancement remains unaffected by halving the irradiated area. This study overcomes the irradiation size limit for photo-assisted ion batteries and encourages highly integrated photo-assisted ion batteries for practice application. An irradiation spillover effect in photo-assisted ion batteries is that the impact of irradiation on the battery is not restrained within the irradiated area but can spill over the whole electrode. Here, the capacity enhancement of the PZIB under illumination remains consistent when the irradiation area is halved. This finding overcomes the irradiation size limit for photo-assisted ion batteries and encourages the highly integrated photo-assisted ion batteries for practice application.image