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Article Abstract
Modulating the electronic structure of catalysts to maximize their power holds the key to address the challenges faced by zinc-iodine batteries (ZIBs), including the shuttle effect and slow redox kinetics at the iodine cathode. Herein, oxygen vacancies is innovatively introduced into CoO lattice to create high-spin-state Co active sites in nonstoichiometric CoO nanocrystals supported by carbon nanofibers (H-CoO/CNFs). This simple strategy intensifies crystal field splitting of Co 3d orbitals, optimizing the spin-orbital coupling between Co 3d orbitals and iodine species. The resulting enhanced availability of more unpaired electrons in non-degenerate e orbitals facilitates faster electron donation/acceptance during iodine redox reactions, thus improved reaction kinetics. Therefore, the assembled ZIBs employing H-CoO/CNFs/I cathode acquires a narrower overpotential gap (37 mV), higher initial capacity (203.0 mAh g), and better cycling stability (96.0% capacity retention after 2200 cycles at 0.5 A g) compared to the CoO/CNFs/I cathode without experiencing defect engineering (109 mV/192.6 mAh g/74.7% after 1000 cycles). This work opens new avenues for maximizing the potential power of cathode host catalysts, making immediate contributions to the advancement of aqueous halogen batteries.
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