The use of nickel-rich layered materials as cathodes
can boost
the energy density of lithium batteries. However, developing a safe
and long-term stable nickel-rich layered cathode is challenging primarily
due to the release of lattice oxygen from the cathode during cycling,
especially at high voltages, which will cause a series of adverse
effects, leading to battery failure and thermal runaway. Surface coating
is often considered effective in capturing active oxygen species;
however, its process is rather complicated, and it is difficult to
maintain intact on the cathode with large volume changes during cycling.
Here, we propose an in situ construction of a multifunctional cathode/electrolyte
interphase (CEI), which is easy to prepare, repairable, and, most
importantly, capable of continuously capturing active oxygen species
during the entire life span. This unique protective mechanism notably
improves the cycling stability of Li||LiNi0.8Co0.1Mn0.1O2 (NCM811) cells at rigorous working
conditions, including ultrahigh voltage (4.8 V), high temperature
(60 °C), and fast charging (10 C). An industrial 1 A h graphite||NCM811
pouch cell achieved stable operation of 600 cycles with a capacity
retention of 79.6% at 4.4 V, exhibiting great potential for practical
use. This work provides insightful guidance for constructing a multifunctional
CEI to bypass limitations associated with high-voltage operations
of nickel-rich layered cathodes.