4 research outputs found
Insights into Electrochemical Sodium Metal Deposition as Probed with <i>in Situ</i> <sup>23</sup>Na NMR
Sodium
batteries have seen a resurgence of interest from researchers
in recent years, owing to numerous favorable properties including
cost and abundance. Here we examine the feasibility of studying this
battery chemistry with <i>in situ</i> NMR, focusing on Na
metal anodes. Quantification of the NMR signal indicates that Na metal
deposits with a morphology associated with an extremely high surface
area, the deposits continually accumulating, even in the case of galvanostatic
cycling. Two regimes for the electrochemical cycling of Na metal are
apparent that have implications for the use of Na anodes: at low currents,
the Na deposits are partially removed on reversing the current, while
at high currents, there is essentially no removal of the deposits
in the initial stages. At longer times, high currents show a significantly
greater accumulation of deposits during cycling, again indicating
a much lower efficiency of removal of these structures when the current
is reversed
In Situ, Real-Time Visualization of Electrochemistry Using Magnetic Resonance Imaging
The drive to develop better electrochemical
energy storage devices
requires the development of not only new materials, but also better
understanding of the underpinning chemical and dynamical processes
within such devices during operation, for which new analytical techniques
are required. Currently, there are few techniques that can probe local
composition and transport in the electrolyte during battery operation.
In this paper, we report a novel application of magnetic resonance
imaging (MRI) for probing electrochemical processes in a model electrochemical
cell. Using MRI, the transport and zinc and oxygen electrochemistry
in an alkaline electrolyte, typical of that found in zinc-air batteries,
are investigated. Magnetic resonance relaxation maps of the electrolyte
are used to visualize the chemical composition and electrochemical
processes occurring during discharge in this model metal-air battery.
Such experiments will be useful in the development of new energy storage/conversion
devices, as well as other electrochemical technologies
Mg<sub><i>x</i></sub>Mn<sub>2–<i>x</i></sub>B<sub>2</sub>O<sub>5</sub> Pyroborates (2/3 ≤ <i>x</i> ≤ 4/3): High Capacity and High Rate Cathodes for Li-Ion Batteries
MgMnB<sub>2</sub>O<sub>5</sub>, Mg<sub>2/3</sub>Mn<sub>4/3</sub>B<sub>2</sub>O<sub>5</sub>, and Mg<sub>4/3</sub>Mn<sub>2/3</sub>B<sub>2</sub>O<sub>5</sub> pyroborates have been prepared via a ceramic
method. When charging MgMnB<sub>2</sub>O<sub>5</sub> vs Li, all of
the Mg<sup>2+</sup> can be removed, and with subsequent cycles, 1.4
Li ions, corresponding to a capacity of 250 mAhg<sup>–1</sup>, can be reversibly intercalated. This is achieved at a C/25 rate
with 99.6% Coulombic efficiency. Significant capacity is retained
at high rates with 97 mAhg<sup>–1</sup> at a rate of 2C. Continuous
cycling at moderate rates gradually improves performance leading to
insertion of 1.8 Li, 314 mAhg<sup>–1</sup> with a specific
energy of 802 Whkg<sup>–1</sup>, after 1000 cycles at C/5.
Ex situ X-ray and neutron diffraction demonstrate the retention of
the pyroborate structure on cycling vs Li and a small volume change
(1%) between the fully lithiated and delithiated structures. Mg<sub>2/3</sub>Mn<sub>4/3</sub>B<sub>2</sub>O<sub>5</sub> and Mg<sub>4/3</sub>Mn<sub>2/3</sub>B<sub>2</sub>O<sub>5</sub> are also shown to reversibly
intercalate Li at 17.8 and 188.6 mAhg<sup>–1</sup>, respectively,
with Mn ions likely blocking Mg/Li transport in the Mg<sub>2/3</sub>Mn<sub>4/3</sub>B<sub>2</sub>O<sub>5</sub> material. The electrochemical
ion-exchange of polyanion materials with labile Mg ions could prove
to be a route to high energy density Li-ion cathodes
Unraveling the Complex Delithiation and Lithiation Mechanisms of the High Capacity Cathode Material V<sub>6</sub>O<sub>13</sub>
V<sub>6</sub>O<sub>13</sub> is a
promising Li-ion battery cathode
material for use in the high temperature oil field environment. The
material exhibits a high capacity, and the voltage profile contains
several plateaus associated with a series of complex structural transformations,
which are not fully understood. The underlying mechanisms are central
to understanding and improving the performance of V<sub>6</sub>O<sub>13</sub>-based rechargeable batteries. In this study, we present <i>in situ</i> X-ray diffraction data that highlight an asymmetric
six-step discharge and five-step charge process, due to a phase that
is only formed on discharge. The Li<sub><i>x</i></sub>V<sub>6</sub>O<sub>13</sub> unit cell expands sequentially in <i>c</i>, <i>b</i>, and <i>a</i> directions during discharge
and reversibly contracts back during charge. The process is associated
with change of Li ion positions as well as charge ordering in Li<sub><i>x</i></sub>V<sub>6</sub>O<sub>13</sub>. Density functional
theory calculations give further insight into the electronic structures
and preferred Li positions in the different structures formed upon
cycling, particularly at high lithium contents, where no prior structural
data are available. The results shed light into the high specific
capacity of V<sub>6</sub>O<sub>13</sub> and are likely to aid in the
development of this material for use as a cathode for secondary lithium
batteries