TY - JOUR
T1 - In Situ Investigation of Lattice Oxygen Loss from Preferentially Faceted Electrodeposited LiCoO2 via Scanning Electrochemical Microscopy
AU - Mishra, Abhiroop
AU - Lin, Jr-Wen
AU - Zahiri, Beniamin
AU - Braun, Paul V.
AU - Rodríguez-López, Joaquín
N1 - A. M. gratefully acknowledges the support from the Link Foundation Energy Fellowship. This work was supported by the U.S. Army Construction Engineering Research Laboratory Award #W9132T2120008. Sample preparation and characterization were conducted, in part, at the Materials Research Laboratory at the University of Illinois.
PY - 2024/5/31
Y1 - 2024/5/31
N2 - Lattice oxygen loss from transition metal oxide cathodes in Li-ion batteries (LiBs) is a key factor responsible in their gradual capacity decline over time. Understanding and mitigating this phenomenon is crucial for the development of next-generation LiBs. The effect of various parameters on lattice oxygen loss, such as cathode chemical composition, has been studied extensively. However, there is a lack of experimental investigation into the lattice oxygen stability across different crystallographic facets within the same cathode composition. Here, we employed in situ scanning electrochemical microscopy (SECM) to investigate oxygen evolution from preferentially faceted, electrodeposited LiCoO2 cathodes. Samples predominantly exposing the (003) basal planes and the (101), (102), (110) fast Li-ion diffusing facets exhibited oxygen evolution at potentials exceeding 3.5 V vs Li+/Li. Finite element simulations helped quantify the flux of oxygen evolution on the first charge cycle to 33 ± 5 pmol cm−2s−1 for the basal plane and 37 ± 9 pmol cm−2s−1 for the faceted samples at potentials above 4 V based on single spot measurements. However, spatially resolved measurements showed that faceted samples exhibited significant heterogeneity in their oxygen evolution, reaching twofold values compared to the basal plane samples at potentials beyond 4.5 V.
AB - Lattice oxygen loss from transition metal oxide cathodes in Li-ion batteries (LiBs) is a key factor responsible in their gradual capacity decline over time. Understanding and mitigating this phenomenon is crucial for the development of next-generation LiBs. The effect of various parameters on lattice oxygen loss, such as cathode chemical composition, has been studied extensively. However, there is a lack of experimental investigation into the lattice oxygen stability across different crystallographic facets within the same cathode composition. Here, we employed in situ scanning electrochemical microscopy (SECM) to investigate oxygen evolution from preferentially faceted, electrodeposited LiCoO2 cathodes. Samples predominantly exposing the (003) basal planes and the (101), (102), (110) fast Li-ion diffusing facets exhibited oxygen evolution at potentials exceeding 3.5 V vs Li+/Li. Finite element simulations helped quantify the flux of oxygen evolution on the first charge cycle to 33 ± 5 pmol cm−2s−1 for the basal plane and 37 ± 9 pmol cm−2s−1 for the faceted samples at potentials above 4 V based on single spot measurements. However, spatially resolved measurements showed that faceted samples exhibited significant heterogeneity in their oxygen evolution, reaching twofold values compared to the basal plane samples at potentials beyond 4.5 V.
KW - batteries - Li-ion
KW - electroanalytical electrochemistry
KW - electrodeposition
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U2 - 10.1149/1945-7111/ad4f22
DO - 10.1149/1945-7111/ad4f22
M3 - Article
VL - 171
SP - 056510
JO - Journal of the Electrochemical Society
JF - Journal of the Electrochemical Society
IS - 5
M1 - 056510
ER -