2 research outputs found
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
Electrode Reaction Mechanism of Ag<sub>2</sub>VO<sub>2</sub>PO<sub>4</sub> Cathode
The high capacity of primary lithium-ion
cathode Ag<sub>2</sub>VO<sub>2</sub>PO<sub>4</sub> is facilitated
by both displacement
and insertion reaction mechanisms. Whether the Ag extrusion (specifically,
Ag reduction with Ag metal displaced from the host crystal) and V
reduction are sequential or concurrent remains unclear. A microscopic
description of the reaction mechanism is required for developing design
rules for new multimechanism cathodes, combining both displacement
and insertion reactions. However, the amorphization of Ag<sub>2</sub>VO<sub>2</sub>PO<sub>4</sub> during lithiation makes the investigation
of the electrode reaction mechanism difficult with conventional characterization
tools. For addressing this issue, a combination of local probes of
pair-distribution function and X-ray spectroscopy were used to obtain
a description of the discharge reaction. We determine that the initial
reaction is dominated by silver extrusion with vanadium playing a
supporting role. Once sufficient Ag has been displaced, the residual
Ag<sup>+</sup> in the host can no longer stabilize the host structure
and V–O environment (i.e., onset of amorphization). After amorphization,
silver extrusion continues but the vanadium reduction dominates the
reaction. As a result, the crossover from primarily silver reduction
displacement to vanadium reduction is facilitated by the amorphization
that makes vanadium reduction increasingly more favorable