What type of study is this?

This is a In Vitro Study study (also classified as: Animal Study, Human Clinical Trial, Pre-Registered Trial, Findings Consistent with Meta-Analysis).

September 10, 2025

Oxygen Vacancies Design of Anionic Site to Optimize Electrode–Electrolyte Interface Properties on a Li-Rich Cathode

Key Points

Controlled oxygen vacancies increased the discharge capacity of lithium-rich cathodes to 305.1 mAh g-1, significantly improving performance and energy density.
Findings show an energy density as high as 1060.0 Wh kg-1, emphasizing the benefits of optimized oxygen vacancy concentration in lithium-rich cathodes.
In situ XRD and soft X-ray absorption spectroscopy were utilized to elucidate how the concentration of oxygen vacancies influences the electrochemical properties.
The results highlight the importance of balancing advantages and disadvantages to enhance the overall performance of lithium-rich cathode materials.

Abstract

Lithium-rich cathode materials (LROs) elicit great interest due to their excellent electrochemical performance and high energy density (>900 Wh kg-1). Anionic redox (AR) contributes additional capacity to LROs but causes unfavorable structural degradation and oxygen release. Surface oxygen vacancies (Vos) in LROs directly affect anion redox, and the effects of their concentration variations have been reported both positively and negatively in the current studies. Therefore, controlling the concentration of Vos is essential to balancing these advantages and disadvantages. In this work, the initial discharge capacity of LROs with an appropriate Vos concentration is increased to 305.1 mAh g-1, with an energy density as high as 1060.0 Wh kg-1. In addition, in situ XRD, soft X-ray absorption spectroscopy (sXAS), and differential electrochemical mass spectrometry (DEMS) were employed to determine and further elucidate the mechanism by which their concentration affects performance.

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