IBS CMSD Seminar_Prof. Hye Ryung Byon (KAIST)(Nov. 14, 2019)
IBS Center for Molecular Spectroscopy and Dynamics
Seminar |
|
■
SPEAKER
Prof. Hye
Ryung Byon (KAIST)
■
TITLE
Understanding Interfacial Reaction of LiCoO2 Positive Electrode in
Aqueous Lithium-Ion Batteries
■ ABSTRACT
Since
the risk of catch fire using non-aqueous electrolyte solution, aqueous
solution-based rechargeable lithium batteries (ARLB) have been highlighted.
However, the conventional positive electrodes of lithium transition-metal oxide
such as LiCoO2 (LCO) and LiNi1/3Mn1/3Co1/3O2 (NMC) have suffered from poor
cyclability in aqueous medium. Representatively, the layered two-dimensional
structure of LCO shows notably poor stability, possibly due to the surface
degradation from water [1] and proton [2]. However, understanding of interfacial
reaction of LCO in the aqueous electrolyte solution is still superficial. Here
we present degradation phenomena of LCO electrode in aqueous medium using
various X-ray measurement techniques, and suggest the solution to avoid such an
irreversible electrochemical reaction. The aqueous solution was prepared with
0.5 M lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) and pH was controlled
to ~6.8 and 10. In both cases, there was no evidence for the formation of
cathode-electrolyte interphase (CEI) on LCO in contrast to the one with
non-aqueous electrolyte solution. The direct contact of aqueous electrolyte
solution to LCO surface results in the short-range disorder of LCO structure
such as the distortion of octahedral CoO6, and irreversible Li+ desertion
during 10 cycles. To improve electrochemical reversibility and structural
stability of LCO, we prepared the organic protection layer that opened the Li+
mass transport route while inhibiting H2O contact from hydrophobic surface. As
a result, the capacity retention was improved to ~85% during 30 cycles at pH ~
6.8. Furthermore, we developed the way to protect LCO surface by anion
engineering and in the absence of protection layer, which give insight into the
inner Helmholtz plane (IHP) structure and its effect for LCO degradation in
aqueous medium.
■ DATE AND VENUE
November 14, 2019 (Thursday, 4:00 - 5:00)
Seminar Room A (116), KU R&D Center
■
INVITED BY
Professor Kyungwon Kwak
■
LANGUAGE
Korean