Exploring
the Role of an Electrolyte Additive in Suppressing
Surface Reconstruction of a Ni-Rich NMC Cathode at Ultrahigh Voltage
via Enhanced In Situ and Operando Characterization Methods
posted on 2024-02-09, 20:05authored byHuidong Dai, Luisa Gomes, Derrick Maxwell, Somayeh Zamani, Kevin Yang, Dianne Atienza, Nilesh Dale, Sanjeev Mukerjee
Vinylene carbonate
(VC) is a widely used electrolyte additive in
lithium-ion batteries for enhanced solid electrolyte interphase formation
on the anode side. However, the cathode electrolyte interphase (CEI)
formation with VC has received a lot less attention. This study presents
a comprehensive investigation employing advanced in situ/operando-based
Raman and X-ray absorption spectroscopy (XAS) to explore the effect
of electrolyte composition on the CEI formation and suppression of
surface reconstruction of LixNiyMnzCo1–y–zO2 (NMC) cathodes.
A novel chemical pathway via VC polymerization is proposed based on
experimental results. In situ Raman spectra revealed a new peak at
995 cm–1, indicating the presence of C–O
semi-carbonates resulting from the radical polymerization of VC. Operando
Raman analysis unveiled the formation of NiO at 490 cm–1 in the baseline system under ultrahigh voltage (up to 5.2 V). However,
this peak was conspicuously absent in the VC electrolyte, signifying
the effectiveness of VC in suppressing surface reconstruction. Further
investigation was carried out utilizing in situ XAS compared X-ray
absorption near edge structure spectra from cells of 3 and 20 cycles
in both electrolytes at different operating voltages. The observed
shift at the Ni K-edge confirmed a more substantial reduction of Ni
in the baseline electrolyte compared to that in the VC electrolyte,
thus indicating less CEI protection in the former. A sophisticated
extended X-ray absorption fine structure analysis quantitatively confirmed
the effective suppression of rock-salt formation with the VC electrolyte
during the charging process, consistent with the operando Raman results.
The in situ XAS results thus provided additional support for the key
findings of this study, establishing the crucial role of VC polymerization
in enhancing CEI stability and mitigating surface reconstruction on
NMC cathodes. This work clarifies the relationship between the enhanced
CEI layer and NMC degradation and inspires rational electrolyte design
for long-cycling NMC cathodes.