In situ constructing a stable interface film on high-voltage LiCoO2 cathode via a novel electrolyte additive

We propose a novel electrolyte additive, 5-acetylthiophene-2-carbonitrile (ATCN) with three functional groups (thiophene, nitrile and carbonyl), to in situ construct a stable cathode interface film that can significantly improve the cycling stability of LiCoO2 cathode under high-voltage. Adding 0.2% of ATCN into a base electrolyte, the capacity retention of LiCoO2/Li cell under 4.5 V is enhanced from 53% to 91% after 200 cycles at 1 C, and the cycle number of commercial LiCoO2/graphite pouch cell (34 Ah) with 10% capacity loss at 0.5 C under a cut-off voltage of 4.45 V is increased from 550 to 800. Experimental characterizations and theoretical calculations reveal that ATCN is preferentially oxidized on LiCoO2 cathode and utilizes its decomposition intermediates to convert the detrimental components, the hydrogen fluoride and water present in the electrolyte, and the lithium oxide and carbonate resulting from the electrolyte decomposition, into a unique film texture comprised of underneath compacted lithium salts and outer thiophene polymers. The as-constructed film significantly improves the cathode/electrolyte interface stability and the cycling stability of the cell. Such an effective strategy to address the interface instability has never been reported before and paves a new path to improve the energy density of commercial lithium-ion batteries via enhancing cut-off charge voltage.

Automated summary

The novel electrolyte additive ATCN is proposed to enhance the stability of LiCoO2 cathode under high-voltage conditions, significantly improving cycling performance. Experimental and theoretical analyses show that ATCN preferentially oxidizes on the cathode, converting detrimental components in the electrolyte into a unique film texture that enhances cathode/electrolyte interface stability and overall cell cycling stability.