4 research outputs found
Atomic Insight into the Layered/Spinel Phase Transformation in Charged LiNi<sub>0.80</sub>Co<sub>0.15</sub>Al<sub>0.05</sub>O<sub>2</sub> Cathode Particles
Layered
LiNi<sub>0.80</sub>Co<sub>0.15</sub>Al<sub>0.05</sub>O<sub>2</sub> (NCA) holds great promise as a potential cathode material
for high energy density lithium ion batteries. However, its high capacity
is heavily dependent on the stability of its layered structure, which
suffers from a severe structure degradation resulting from a not fully
understood layered → spinel phase transformation. Using high-resolution
transmission electron microscopy and electron diffraction, we probe
the atomic structure evolution induced by the layered → spinel
phase transformation in the NCA cathode. We show that the phase transformation
results in the development of a particle structure with the formation
of complete spinel, spinel domains, and intermediate spinel from the
surface to the subsurface region. The lattice planes of the complete
and intermediate spinel phases are highly interwoven in the subsurface
region. The layered → spinel transformation occurs via the
migration of transition metal (TM) atoms from the TM layer into the
lithium layer. Incomplete migration leads to the formation of the
intermediate spinel phase, which is featured by tetrahedral occupancy
of TM cations in the lithium layer. The crystallographic structure
of the intermediate spinel is discussed and verified by the simulation
of electron diffraction patterns
Tuning the Activity of Oxygen in LiNi<sub>0.8</sub>Co<sub>0.15</sub>Al<sub>0.05</sub>O<sub>2</sub> Battery Electrodes
Layered transition metal oxides such
as LiNi<sub>0.8</sub>Co <sub>0.15</sub>Al<sub>0.05</sub>O<sub>2</sub> (NCA) are highly desirable battery electrodes. However, these materials
suffer from thermal runaway caused by deleterious oxygen loss and
surface phase transitions when in highly overcharged and overheated
conditions, prompting serious safety concerns. Using in situ environmental
transmission electron microscopy techniques, we demonstrate that surface
oxygen loss and structural changes in the highly overcharged NCA particles
are suppressed by exposing them to an oxygen-rich environment. The
onset temperature for the loss of oxygen from the electrode particle
is delayed to 350 °C at oxygen gas overpressure of 400 mTorr.
Similar heating of the particles in a reducing hydrogen gas demonstrated
a quick onset of oxygen loss at 150 °C and rapid surface degradation
of the particles. The results reported here illustrate the fundamental
mechanism governing the failure processes of electrode particles and
highlight possible strategies to circumvent such issues
What Happens to LiMnPO<sub>4</sub> upon Chemical Delithiation?
Olivine MnPO<sub>4</sub> is the delithiated
phase of the lithium-ion-battery cathode (positive electrode) material
LiMnPO<sub>4</sub>, which is formed at the end of charge. This phase
is metastable under ambient conditions and can only be produced by
delithiation of LiMnPO<sub>4</sub>. We have revealed the manganese
dissolution phenomenon during chemical delithiation of LiMnPO<sub>4</sub>, which causes amorphization of olivine MnPO<sub>4</sub>.
The properties of crystalline MnPO<sub>4</sub> obtained from carbon-coated
LiMnPO<sub>4</sub> and of the amorphous product resulting from delithiation
of pure LiMnPO<sub>4</sub> were studied and compared. The phosphorus-rich
amorphous phases in the latter are considered to be MnHP<sub>2</sub>O<sub>7</sub> and MnH<sub>2</sub>P<sub>2</sub>O<sub>7</sub> from
NMR, X-ray absorption spectroscopy, and X-ray photoelectron spectroscopy
analysis. The thermal stability of MnPO<sub>4</sub> is significantly
higher under high vacuum than at ambient condition, which is shown
to be related to surface water removal
Electrochemical Performance of Nanosized Disordered LiVOPO<sub>4</sub>
ε-LiVOPO<sub>4</sub> is a promising multielectron cathode
material for Li-ion batteries that can accommodate two electrons per
vanadium, leading to higher energy densities. However, poor electronic
conductivity and low lithium ion diffusivity currently result in low
rate capability and poor cycle life. To enhance the electrochemical
performance of ε-LiVOPO<sub>4</sub>, in this work, we optimized
its solid-state synthesis route using in situ synchrotron X-ray diffraction
and applied a combination of high-energy ball-milling with electronically
and ionically conductive coatings aiming to improve bulk and surface
Li diffusion. We show that high-energy ball-milling, while reducing
the particle size also introduces structural disorder, as evidenced
by <sup>7</sup>Li and <sup>31</sup>P NMR and X-ray absorption spectroscopy.
We also show that a combination of electronically and ionically conductive
coatings helps to utilize close to theoretical capacity for ε-LiVOPO<sub>4</sub> at C/50 (1 C = 153 mA h g<sup>–1</sup>) and to enhance
rate performance and capacity retention. The optimized ε-LiVOPO<sub>4</sub>/Li<sub>3</sub>VO<sub>4</sub>/acetylene black composite yields
the high cycling capacity of 250 mA h g<sup>–1</sup> at C/5
for over 70 cycles