posted on 2022-08-26, 11:34authored byLori A. Kaufman, Tzu-Yang Huang, Donghun Lee, Bryan D. McCloskey
High-Ni layered oxide cathode materials (LiNixTM(1–x)O2, where x > 0.8) are of great interest because
they offer increased
capacity compared to current commercial materials within a narrow
voltage range. However, recent studies have shown that these materials
in their current form suffer from capacity fading when an upper cutoff
voltage above 4.3 V vs Li/Li+ is used. While many studies
have focused on the H2 → H3 transition as the primary cause
of capacity fading, gas evolution studies show that degradation processes
cannot be attributed to the H2 → H3 transition alone. In this
work, differential electrochemical mass spectrometry (DEMS) is combined
with titration mass spectrometry (TiMS) to measure gases evolved in
a lithium half-cell during cycling as well as surface species which
evolve gas upon addition of strong acid to an extracted cathode. Along
with qualitative observations of particle cracking by scanning electron
microscopy (SEM), these results reveal correlations between particle
cracking, electrolyte reactivity, and carbonate oxidation and deposition
on the cathode surface during the first charge of high-Ni cathode
materials.