Voltage Dependent Solid Electrolyte Interphase Formation
in Silicon Electrodes: Monitoring the Formation of Organic Decomposition
Products
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Abstract
The solid electrolyte interphase
(SEI) passivating layer that grows
on all battery electrodes during cycling is critical to the long-term
capacity retention of lithium-ion batteries. Yet, it is inherently
difficult to study because of its nanoscale thickness, amorphous composite
structure, and air sensitivity. Here, we employ an experimental strategy
using <sup>1</sup>H, <sup>7</sup>Li, <sup>19</sup>F, and <sup>13</sup>C solid-state nuclear magnetic resonance (ssNMR) to gain insight
into the decomposition products in the SEI formed on silicon electrodes,
the uncontrolled growth of the SEI representing a major failure mechanism
that prevents the practical use of silicon in lithium-ion batteries.
The voltage dependent formation of the SEI is confirmed, with the
SEI growth correlating with irreversible capacity. By studying both
conductive carbon and mixed Si/C composite electrodes separately,
a correlation with increased capacity loss of the composite system
and the low-voltage silicon plateau is demonstrated. Using selective <sup>13</sup>C labeling, we detect decomposition products of the electrolyte
solvents ethylene carbonate (EC) and dimethyl carbonate (DMC) independently.
EC decomposition products are present in higher concentrations and
are dominated by oligomer species. Lithium semicarbonates, lithium
fluoride, and lithium carbonate products are also seen. Ab initio
calculations have been carried out to aid in the assignment of NMR
shifts. ssNMR applied to both rinsed and unrinsed electrodes show
that the organics are easily rinsed away, suggesting that they are
located on the outer layer of the SEI