posted on 2017-02-16, 00:00authored byTianyuan Ma, Gui-Liang Xu, Yan Li, Li Wang, Xiangming He, Jianming Zheng, Jun Liu, Mark H. Engelhard, Peter Zapol, Larry A. Curtiss, Jacob Jorne, Khalil Amine, Zonghai Chen
The
corrosion of aluminum current collectors and the oxidation
of solvents at a relatively high potential have been widely investigated
with an aim to stabilize the electrochemical performance of lithium-ion
batteries using such components. The corrosion behavior of aluminum
current collectors was revisited using a home-build high-precision
electrochemical measurement system, and the impact of electrolyte
components and the surface protection layer on aluminum foil was systematically
studied. The electrochemical results showed that the corrosion of
aluminum foil was triggered by the electrochemical oxidation of solvent
molecules, like ethylene carbonate, at a relative high potential.
The organic radical cations generated from the electrochemical oxidation
are energetically unstable and readily undergo a deprotonation reaction
that generates protons and promotes the dissolution of Al3+ from the aluminum foil. This new reaction mechanism can also shed
light on the dissolution of transitional metal at high potentials.