posted on 2023-02-24, 16:07authored byKen-ichi Inoue, Jianxin Mao, Rika Okamoto, Yutaka Shibata, Wenbo Song, Shen Ye
Electrochemical reactions in practical batteries occur
in confined
environments where anode and cathode electrodes are separated only
by a thin separator. Therefore, their electrochemical behaviors may
differ from those obtained in the conventional experimental cells,
where the two electrodes (working and counter electrodes) are largely
separated compared to the batteries. The spatial and temporal distributions
of the chemical species in the vicinity of each electrode are highly
expected to be determined for quantitatively understanding the phenomena
in confined environments. In the present study, we developed a line-detected
UV–vis absorption microscope that simultaneously measures space-resolved
UV–vis absorption spectra. This novel technique has been successfully
applied to evaluate the reactivities of the highly reactive lithium
(Li) surfaces in organic electrolyte solutions under in situ conditions. The quantitative evaluations of the dissolution rate
of Li and the diffusion constant of the product were successfully
realized by analyzing the space- and time-resolved absorption spectra
based on Fick’s law of diffusion. The microscopic technique
is expected to open the door to understanding the fundamental electrochemistry
in batteries.