AI Article Synopsis
- Flexible solid-state zinc-air batteries have been developed for wearable energy storage, featuring gel electrolyte separators that enhance ion permeability and limit zinc dendrite formation.
- However, these gel separators face challenges like poor electrolyte affinity and ionic conductivity, hindering broader application.
- To tackle these issues, TiO was added to cellulose acetate/polyvinyl alcohol nanofibers to improve porosity and glutaraldehyde was used to strengthen the structure, achieving an optimal configuration that significantly increased separator porosity and absorption rate while enhancing discharge capacity and cycling stability.
Article Abstract
Flexible solid-state zinc-air batteries as a wearable energy storage device with great potential, and their separators, which control ion permeability, inhibit zinc dendrite generation, and regulate catalytic active sites, have been developed as gel electrolyte separators with high retention of electrolyte uptake. However, the gel electrolyte separator still has problems such as poor affinity with the electrolyte and poor ionic conductivity, which limits its further application. In order to further improve the electrolyte absorption, ionic conductivity and mechanical strength of cellulose acetate(CA)/polyvinyl alcohol (PVA) nanofibers, TiOwas added to CA/PVA to increase the porosity, and glutaraldehyde (GA) was used to modify the CA/PVA/TiOseparator by acetal reaction with CA and PVA to make the molecules closely linked. The results shows that the optimal mass fractions of TiOand GA were 2% and 5%, respectively. At this time, the porosity and absorption rate of the separator increased from 48% to 68.2% and 142.4% to 285.3%, respectively. The discharge capacity reached 179 mA cm, and the cycle stability rate was 89% after 7 stable constant current charge/discharge cycles.
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| http://dx.doi.org/10.1088/1361-6528/ad0f56 | DOI Listing |
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