posted on 2020-07-13, 15:35authored byKatharina Thanner, Alberto Varzi, Daniel Buchholz, Stefan J. Sedlmaier, Stefano Passerini
In this study, the artificial solid electrolyte interphase (SEI)
formed on lithium metal when treated in ZnCl2 solutions
is thoroughly investigated. The artificial SEI on lithium metal electrodes
substantially decreases the interfacial resistance by ca. 80% and
improves cycling stability in comparison to untreated lithium. The
presence of a native SEI negatively affects the morphology and interfacial
resistance of the artificial SEI. Increasing the ZnCl2 concentration
in tetrahydrofuran (THF) (precursor solution) results in higher homogeneity
of the surface morphology. Independent of the ZnCl2 concentrations,
the artificial SEI is composed of Cx,
CO, LiCl, Li2CO3, ZnCl2, and LixZny alloys. ZnCl2 (1 M) produces the most homogenous surface and additional
surface species with carbonyl side groups. Nonetheless, the ZnCl2 concentration only has a small effect on the interfacial
resistance or cycling stability. Using ethyl methyl carbonate (EMC)
as the solvent significantly reduces the interfacial resistance to
7 Ω cm2, in comparison to 25 Ω cm2 for THF. The composition of the artificial SEIs varies depending
on the solvent. Either way, the SEI consists of Cx LixC, LiCl, Li2CO3, ZnCl2, and LiZn alloys. The THF-based SEI additionally
features ether and carbonyl groups, LiZnO, and Zn metal. For the artificial
SEI formed with both solvents, the atomic percentage of the LiZn alloy
increases close to the Li surface.